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Endocytosis and Trafficking of Natriuretic Peptide Receptor-A:
Potential Role of Short Sequence Motifs
PubMed Central
Pandey, Kailash N.
2015-01-01
The targeted endocytosis and redistribution of transmembrane
receptors among membrane-bound subcellular organelles are vital for
their correct signaling and physiological functions. Membrane
receptors committed for internalization and trafficking pathways
are sorted into coated vesicles. Cardiac hormones, atrial and brain
natriuretic peptides (ANP and BNP) bind to guanylyl
cyclase/natriuretic peptide receptor-A (GC-A/NPRA) and elicit the
generation of intracellular second messenger cyclic guanosine
3',5'-monophosphate (cGMP), which lowers blood pressure and
incidence of heart failure. After ligand binding, the receptor is
rapidly internalized, sequestrated, and redistributed into
intracellular locations. Thus, NPRA is considered a dynamic
cellular macromolecule that traverses different subcellular
locations through its lifetime. The utilization of pharmacologic
and molecular perturbants has helped in delineating the pathways of
endocytosis, trafficking, down-regulation, and degradation of
membrane receptors in intact cells. This review describes the
investigation of the mechanisms of internalization, trafficking,
and redistribution of NPRA compared with other cell surface
receptors from the plasma membrane into the cell interior. The
roles of different short-signal peptide sequence motifs in the
internalization and trafficking of other membrane receptors have
been briefly reviewed and their potential significance in the
internalization and trafficking of NPRA is discussed.
PMID:26151885
Potential of known and short prokaryotic protein motifs as a
basis for novel peptide-based antibacterial therapeutics: a
computational survey
PubMed Central
Ruhanen, Heini; Hurley, Daniel; Ghosh, Ambarnil; O'Brien, Kevin
T.; Johnston, Catrina R.; Shields, Denis C.
2014-01-01
Short linear motifs (SLiMs) are functional stretches of protein
sequence that are of crucial importance for numerous biological
processes by mediating proteinprotein interactions. These motifs
often comprise peptides of less than 10 amino acids that modulate
proteinprotein interactions. While well-characterized in eukaryotic
intracellular signaling, their role in prokaryotic signaling is
less well-understood. We surveyed the distribution of known motifs
in prokaryotic extracellular and virulence proteins across a range
of bacterial species and conducted searches for novel motifs in
virulence proteins. Many known motifs in virulence effector
proteins mimic eukaryotic motifs and enable the pathogen to control
the intracellular processes of their hosts. Novel motifs were
detected by finding those that had evolved independently in three
or more unrelated virulence proteins. The search returned several
significantly over-represented linear motifs of which some were
known motifs and others are novel candidates with potential roles
in bacterial pathogenesis. A putative C-terminal G[AG].$ motif
found in type IV secretion system proteins was among the most
significant detected. A KK$ motif that has been previously
identified in a plasminogen-binding protein, was demonstrated to be
enriched across a number of adhesion and lipoproteins. While there
is some potential to develop peptide drugs against bacterial
infection based on bacterial peptides that mimic host components,
this could have unwanted effects on host signaling. Thus, novel
SLiMs in virulence factors that do not mimic host components but
are crucial for bacterial pathogenesis, such as the type IV
secretion system, may be more useful to develop as leads for
anti-microbial peptides or drugs. PMID:24478765
The Configuration of the WWW Motif of a Short Trp-Rich Peptide
Is Critical for Targeting Bacterial Membranes, Disrupting Preformed
Biofilms, and Killing Methicillin-Resistant Staphylococcus
aureus.
PubMed
Zarena, D; Mishra, Biswajit; Lushnikova, Tamara; Wang, Fangyu;
Wang, Guangshun
2017-08-08
Tryptophan-rich peptides, being short and suitable for
large-scale chemical synthesis, are attractive candidates for
developing a new generation of antimicrobials to combat
antibiotic-resistant bacteria (superbugs). Although there are
numerous pictures of the membrane-bound structure of a single
tryptophan (W), how multiple Trp amino acids assemble themselves
and interact with bacterial membranes is poorly understood. This
communication presents the three-dimensional structure of an
eight-residue Trp-rich peptide (WWWLRKIW-NH 2 with 50% W)
determined by the improved two-dimensional nuclear magnetic
resonance method, which includes the measurements of 13 C and 15 N
chemical shifts at natural abundance. This peptide forms the
shortest two-turn helix with a distinct amphipathic feature. A
unique structural arrangement is identified for the Trp triplet,
WWW, that forms a configuration with W2 as the horizontal bar and
W1/W3 forming the two legs. An arginine scan reveals that the WWW
motif is essential for killing methicillin-resistant Staphylococcus
aureus USA300 and disrupting preformed bacterial biofilms. This
unique configuration for the WWW motif is stabilized by
aromatic-aromatic interactions as evidenced by ring current shifts
as well as nuclear Overhauser effects. Because the WWW motif is
maintained, a change of I7 to R led to a potent antimicrobial and
antibiofilm peptide with 4-fold improvement in cell selectivity.
Collectively, this study elucidated the structural basis of
antibiofilm activity of the peptide, identified a better peptide
candidate via structure-activity relationship studies, and laid the
foundation for engineering future antibiotics based on the WWW
motif.
Use of BONSAI decision trees for the identification of potential
MHC class I peptide epitope motifs.
PubMed
Savoie, C J; Kamikawaji, N; Sasazuki, T; Kuhara, S
1999-01-01
Recognition of short peptides of 8 to 10 mer bound to MHC class
I molecules by cytotoxic T lymphocytes forms the basis of cellular
immunity. While the sequence motifs necessary for binding of
intracellular peptides to MHC have been well studied, little is
known about sequence motifs that may cause preferential affinity to
the T cell receptor and/or preferential recognition and response by
T cells. Here we demonstrate that computational learning systems
can be useful to elucidate sequence motifs that affect T cell
activation. Knowledge of T cell activation motifs could be useful
for targeted vaccine design or immunotherapy. With the BONSAI
computational learning algorithm, using a database of previously
reported MHC bound peptides that had positive or negative T cell
responses, we were able to identify sequence motif rules that
explain 70% of positive T cell responses and 84% of negative T cell
responses.
Rapid Identification of Protein Kinase Phosphorylation Site
Motifs Using Combinatorial Peptide Libraries.
PubMed
Miller, Chad J; Turk, Benjamin E
2016-01-01
Eukaryotic protein kinases phosphorylate substrates at serine,
threonine, and tyrosine residues that fall within the context of
short sequence motifs. Knowing the phosphorylation site motif for a
protein kinase facilitates designing substrates for kinase assays
and mapping phosphorylation sites in protein substrates. Here, we
describe an arrayed peptide library protocol for rapidly
determining kinase phosphorylation consensus sequences. This method
uses a set of peptide mixtures in which each of the 20 amino acid
residues is systematically substituted at nine positions
surrounding a central site of phosphorylation. Peptide mixtures are
arrayed in multiwell plates and analyzed by radiolabel assay with
the kinase of interest. The preferred sequence is determined from
the relative rate of phosphorylation of each peptide in the array.
Consensus peptides based on these sequences typically serve as
efficient and specific kinase substrates for high-throughput
screening or incorporation into biosensors.
BlockLogo: visualization of peptide and sequence motif
conservation
PubMed Central
Olsen, Lars Rnn; Kudahl, Ulrich Johan; Simon, Christian; Sun,
Jing; Schnbach, Christian; Reinherz, Ellis L.; Zhang, Guang Lan;
Brusic, Vladimir
2013-01-01
BlockLogo is a web-server application for visualization of
protein and nucleotide fragments, continuous protein sequence
motifs, and discontinuous sequence motifs using calculation of
block entropy from multiple sequence alignments. The user input
consists of a multiple sequence alignment, selection of motif
positions, type of sequence, and output format definition. The
output has BlockLogo along with the sequence logo, and a table of
motif frequencies. We deployed BlockLogo as an online application
and have demonstrated its utility through examples that show
visualization of T-cell epitopes and B-cell epitopes (both
continuous and discontinuous). Our additional example shows a
visualization and analysis of structural motifs that determine
specificity of peptide binding to HLA-DR molecules. The BlockLogo
server also employs selected experimentally validated prediction
algorithms to enable on-the-fly prediction of MHC binding affinity
to 15 common HLA class I and class II alleles as well as visual
analysis of discontinuous epitopes from multiple sequence
alignments. It enables the visualization and analysis of structural
and functional motifs that are usually described as regular
expressions. It provides a compact view of discontinuous motifs
composed of distant positions within biological sequences.
BlockLogo is available at:
http://research4.dfci.harvard.edu/cvc/blocklogo/ and
http://methilab.bu.edu/blocklogo/ PMID:24001880
Generation of high-performance binding proteins for peptide
motifs by affinity clamping
PubMed Central
Koide, Shohei; Huang, Jin
2013-01-01
We describe concepts and methodologies for generating Affinity
Clamps, a new class of recombinant binding proteins that achieve
high affinity and high specificity toward short peptide motifs of
biological importance, which is a major challenge in protein
engineering. The Affinity Clamping concept exploits the potential
of nonhomologous recombination of protein domains in generating
large changes in protein function and the inherent binding affinity
and specificity of the so-called modular interaction domains toward
short peptide motifs. Affinity Clamping creates a clamshell
architecture that clamps onto a target peptide. The design
processes involve (i) choosing a starting modular interaction
domain appropriate for the target and applying structure-guided
modifications, (ii) attaching a second domain, termed enhancer
domain and (iii) optimizing the peptide-binding site located
between the domains by directed evolution. The two connected
domains work synergistically to achieve high levels of affinity and
specificity that are unattainable with either domain alone. Because
of the simple and modular architecture, affinity clamps are
particularly well suited as building blocks for designing more
complex functionalities. Affinity Clamping represents a major
advance in protein design that is broadly applicable to the
recognition of peptide motifs. PMID:23422435
Peptomics, identification of novel cationic Arabidopsis peptides
with conserved sequence motifs.
PubMed
Olsen, Addie Nina; Mundy, John; Skriver, Karen
2002-01-01
Few plant peptides involved in intercellular communication have
been experimentally isolated. Sequence analysis of the Arabidopsis
thaliana genome has revealed numerous transmembrane receptors
predicted to bind proteinacious ligands, emphasizing the importance
of identifying peptides with signaling function. Annotation of the
Arabidopsis genome sequence has made it possible to identify
peptide-encoding genes. However, such annotational identification
is impeded because small genes are poorly predicted by
gene-prediction algorithms, thus prompting the alternative
approaches described here. We initially performed a systematic
analysis of short polypeptides encoded by annotated genes on two
Arabidopsis chromosomes using SignalP to identify potentially
secreted peptides. Subsequent homology searches with selected,
putatively secreted peptides, led to the identification of a
potential, large Arabidopsis family of 34 genes. The predicted
peptides are characterized by a conserved C-terminal sequence motif
and additional primary structure conservation in a core region. The
majority of these genes had not previously been annotated. A subset
of the predicted peptides show high overall sequence similarity to
Rapid Alkalinization Factor (RALF), a peptide isolated from
tobacco. We therefore refer to this peptide family as RALFL for
RALF-Like. RT-PCR analysis confirmed that several of the
Arabidopsis genes are expressed and that their expression patterns
vary. The identification of a large gene family in the genome of
the model organism Arabidopsis thaliana demonstrates that a
combination of systematic analysis and homology searching can
contribute to peptide discovery.
Prediction of peptides binding to MHC class I and II alleles by
temporal motif mining
PubMed Central
2013-01-01
Background MHC (Major Histocompatibility Complex) is a key
player in the immune response of most vertebrates. The
computational prediction of whether a given antigenic peptide will
bind to a specific MHC allele is important in the development of
vaccines for emerging pathogens, the creation of possibilities for
controlling immune response, and for the applications of
immunotherapy. One of the problems that make this computational
prediction difficult is the detection of the binding core region in
peptides, coupled with the presence of bulges and loops causing
variations in the total sequence length. Most machine learning
methods require the sequences to be of the same length to
successfully discover the binding motifs, ignoring the length
variance in both motif mining and prediction steps. In order to
overcome this limitation, we propose the use of time-based motif
mining methods that work position-independently. Results The
prediction method was tested on a benchmark set of 28 different
alleles for MHC class I and 27 different alleles for MHC class II.
The obtained results are comparable to the state of the art methods
for both MHC classes, surpassing the published results for some
alleles. The average prediction AUC values are 0.897 for class I,
and 0.858 for class II. Conclusions Temporal motif mining using
partial periodic patterns can capture information about the
sequences well enough to predict the binding of the peptides and is
comparable to state of the art methods in the literature. Unlike
neural networks or matrix based predictors, our proposed method
does not depend on peptide length and can work with both short and
long fragments. This advantage allows better use of the available
training data and the prediction of peptides of uncommon lengths.
PMID:23368521
Profile-based short linear protein motif discovery
PubMed Central
2012-01-01
Background Short linear protein motifs are attracting increasing
attention as functionally independent sites, typically 310 amino
acids in length that are enriched in disordered regions of
proteins. Multiple methods have recently been proposed to discover
over-represented motifs within a set of proteins based on simple
regular expressions. Here, we extend these approaches to
profile-based methods, which provide a richer motif representation.
Results The profile motif discovery method MEME performed
relatively poorly for motifs in disordered regions of proteins.
However, when we applied evolutionary weighting to account for
redundancy amongst homologous proteins, and masked out poorly
conserved regions of disordered proteins, the performance of MEME
is equivalent to that of regular expression methods. However, the
two approaches returned different subsets within both a benchmark
dataset, and a more realistic discovery dataset. Conclusions
Profile-based motif discovery methods complement regular expression
based methods. Whilst profile-based methods are computationally
more intensive, they are likely to discover motifs currently
overlooked by regular expression methods. PMID:22607209
Supramolecular hydrogels based on short peptides linked with
conformational switch.
PubMed
Huang, Yucheng; Qiu, Zhenjun; Xu, Yanmei; Shi, Junfeng; Lin,
Hongkun; Zhang, Yan
2011-04-07
Short peptides appropriately linked with an azobenzene
conformational switch were found to be motif and pH dependant
supramolecular hydrogelators. The hydrogelation properties of the
short peptides linked with the conformational switch were studied
in detail with respect to dependence on amino acid residue, pH and
salt effect. The presence of amino acids with aromatic side chains
such as Phe and Tyr was found to be favorable for the short
peptides to gel water at an appropriate pH range. Cationic amino
acid residues such as Arg and Lys in the short peptides were found
to be unfavorable for hydrogelation. pH and salt effect were also
found to be important factors for the hydrogelation properties of
the short peptides. A series of short peptides with bioactive
sequences were linked with the conformational switch and their
hydrogelation properties were investigated. Photoresponsive
supramolecular hydrogels were realized based on the E-/Z-
transition of the conformational switch upon light irradiation.
Proper combination of amino acid residues in the short peptides
resulted in smart supramolecular hydrogels with responses to
multiple stimuli.
Short sequence motifs, overrepresented in mammalian
conservednon-coding sequences
SciTech Connect
Minovitsky, Simon; Stegmaier, Philip; Kel, Alexander;
Kondrashov,Alexey S.; Dubchak, Inna
2007-02-21
Background: A substantial fraction of non-coding DNAsequences of
multicellular eukaryotes is under selective constraint.
Inparticular, ~;5 percent of the human genome consists of
conservednon-coding sequences (CNSs). CNSs differ from other
genomic sequences intheir nucleotide composition and must play
important functional roles,which mostly remain obscure.Results: We
investigated relative abundancesof short sequence motifs in all
human CNSs present in the human/mousewhole-genome alignments vs.
three background sets of sequences: (i)weakly conserved or
unconserved non-coding sequences (non-CNSs); (ii)near-promoter
sequences (located between nucleotides -500 and -1500,relative to a
start of transcription); and (iii) random sequences withthe same
nucleotide composition as that of CNSs. When compared tonon-CNSs
and near-promoter sequences, CNSs possess an excess of
AT-richmotifs, often containing runs of identical nucleotides. In
contrast, whencompared to random sequences, CNSs contain an excess
of GC-rich motifswhich, however, lack CpG dinucleotides. Thus,
abundance of short sequencemotifs in human CNSs, taken as a whole,
is mostly determined by theiroverall compositional properties and
not by overrepresentation of anyspecific short motifs. These
properties are: (i) high AT-content of CNSs,(ii) a tendency,
probably due to context-dependent mutation, of A's andT's to clump,
(iii) presence of short GC-rich regions, and (iv) avoidanceof CpG
contexts, due to their hypermutability. Only a small number ofshort
motifs, overrepresented in all human CNSs are similar to
bindingsites of transcription factors from the FOX
family.Conclusion: Human CNSsas a whole appear to be too broad a
class of sequences to possess strongfootprints of any short
sequence-specific functions. Such footprintsshould be studied at
the level of functional subclasses of CNSs, such asthose which
flank genes with a particular pattern of expression.
Overallproperties of CNSs are affected by patterns in
Sequence-Specific DNA Binding by a Short Peptide Dimer
NASA Astrophysics Data System (ADS)
Talanian, Robert V.; McKnight, C. James; Kim, Peter S.
1990-08-01
A recently described class of DNA binding proteins is
characterized by the "bZIP" motif, which consists of a basic region
that contacts DNA and an adjacent "leucine zipper" that mediates
protein dimerization. A peptide model for the basic region of the
yeast transcriptional activator GCN4 has been developed in which
the leucine zipper has been replaced by a disulfide bond. The
34-residue peptide dimer, but not the reduced monomer, binds DNA
with nanomolar affinity at 4^circC. DNA binding is
sequence-specific as judged by deoxyribonuclease I footprinting.
Circular dichroism spectroscopy suggests that the peptide adopts a
helical structure when bound to DNA. These results demonstrate
directly that the GCN4 basic region is sufficient for
sequence-specific DNA binding and suggest that a major function of
the GCN4 leucine zipper is simply to mediate protein dimerization.
Our approach provides a strategy for the design of short
sequence-specific DNA binding peptides.
Minimal motif peptide structure of metzincin clan zinc
peptidases in micelles.
PubMed
Onoda, Akira; Suzuki, Takako; Ishizuka, Hiroaki; Sugiyama,
Rumiko; Ariyasu, Shinya; Yamamura, Takeshi
2009-12-01
It is well known that the functions of metalloproteins generally
originate from their metal-binding motifs. However, the intrinsic
nature of individual motifs remains unknown, particularly the
details about metal-binding effects on the folding of motifs; the
converse is also unknown, although there is no doubt that the motif
is the core of the reactivity for each metalloprotein. In this
study, we focused our attention on the zinc-binding motif of the
metzincin clan family, HEXXHXXGXXH; this family contains the
general zinc-binding sequence His-Glu-Xaa-Xaa-His (HEXXH) and the
extended GXXH region. We adopted the motif sequence of
stromelysin-1 and investigated the folding properties of the
Trp-labeled peptides WAHEIAHSLGLFHA (STR-W1), AWHEIAHSLGLFHA
(STR-W2), AHEIAHSLGWFHA (STR-W11), and AHEIAHSLGLFHWA (STR-W14) in
the presence and absence of zinc ions in hydrophobic micellar
environments by circular dichroism (CD) measurements. We accessed
successful incorporation of these zinc peptides into micelles using
quenching of Trp fluorescence. Results of CD studies indicated that
two of the Trp-incorporated peptides, STR-W1 and STR-W14, exhibited
helical folding in the hydrophobic region of cetyltrimethylammonium
chloride micelle. The NMR structural analysis of the apo STR-W14
revealed that the conformation in the C-terminus GXXH region
significantly differred between the apo state in the micelle and
the reported Zn-bound state of stromelysin-1 in crystal structures.
The structural analyses of the qualitative Zn-binding properties of
this motif peptide provide an interesting Zn-binding mechanism: the
minimum consensus motif in the metzincin clan, a basic zinc-binding
motif with an extended GXXH region, has the potential to serve as a
preorganized Zn binding scaffold in a hydrophobic environment. (c)
2009 European Peptide Society and John Wiley & Sons, Ltd.
Short linear motif core and flanking regions modulate
retinoblastoma protein binding affinity and specificity.
PubMed
Palopoli, Nicols; Gonzlez Foutel, Nicols S; Gibson, Toby J;
Chemes, Luca B
2018-01-23
Pocket proteins retinoblastoma (pRb), p107 and p130 are negative
regulators of cellular proliferation and multifunctional proteins
regulating development, differentiation and chromatin structure.
The retinoblastoma protein is a potent tumor suppressor mutated in
a wide range of human cancers, and oncogenic viruses often
interfere with cell cycle regulation by inactivating pRb. The LxCxE
and pRb AB groove short linear motifs (SLiMs) are key to many
pocket protein mediated interactions including host and viral
partners. A review of available experimental evidence reveals that
several core residues composing each motif instance are
determinants for binding. In the LxCxE motif, a fourth hydrophobic
position that might allow variable spacing is required for binding.
In both motifs, flanking regions including charged stretches and
phosphorylation sites can fine-tune the binding affinity and
specificity of pocket protein SLiM-mediated interactions. Flanking
regions can modulate pocket protein binding specificity, or tune
the high affinity interactions of viral proteins that hijack the
pRb network. The location of SLiMs within intrinsically disordered
regions allows faster evolutionary rates that enable viruses to
acquire a functional variant of the core motif by convergent
evolution, and subsequently test numerous combinations of flanking
regions towards maximizing interaction specificity and affinity.
This knowledge can guide future efforts directed at the design of
peptide-based compounds that can target pocket proteins to regulate
the G1/S cell cycle checkpoint or impair viral mediated pRb
inactivation. The Author(s) 2018. Published by Oxford University
Press. All rights reserved. For Permissions, please e-mail:
[email protected].
Peptide-binding motifs of two common equine class I MHC
molecules in Thoroughbred horses.
PubMed
Bergmann, Tobias; Lindvall, Mikaela; Moore, Erin; Moore, Eugene;
Sidney, John; Miller, Donald; Tallmadge, Rebecca L; Myers, Paisley
T; Malaker, Stacy A; Shabanowitz, Jeffrey; Osterrieder, Nikolaus;
Peters, Bjoern; Hunt, Donald F; Antczak, Douglas F; Sette,
Alessandro
2017-05-01
Quantitative peptide-binding motifs of MHC class I alleles
provide a valuable tool to efficiently identify putative T cell
epitopes. Detailed information on equine MHC class I alleles is
still very limited, and to date, only a single equine MHC class I
allele, Eqca-1*00101 (ELA-A3 haplotype), has been characterized.
The present study extends the number of characterized ELA class I
specificities in two additional haplotypes found commonly in the
Thoroughbred breed. Accordingly, we here report quantitative
binding motifs for the ELA-A2 allele Eqca-16*00101 and the ELA-A9
allele Eqca-1*00201. Utilizing analyses of endogenously bound and
eluted ligands and the screening of positional scanning
combinatorial libraries, detailed and quantitative peptide-binding
motifs were derived for both alleles. Eqca-16*00101 preferentially
binds peptides with aliphatic/hydrophobic residues in position 2
and at the C-terminus, and Eqca-1*00201 has a preference for
peptides with arginine in position 2 and hydrophobic/aliphatic
residues at the C-terminus. Interestingly, the Eqca-16*00101 motif
resembles that of the human HLA A02-supertype, while the
Eqca-1*00201 motif resembles that of the HLA B27-supertype and two
macaque class I alleles. It is expected that the identified motifs
will facilitate the selection of candidate epitopes for the study
of immune responses in horses.
Discovery of novel antimicrobial peptides with unusual cysteine
motifs in dandelion Taraxacum officinale Wigg. flowers.
PubMed
Astafieva, A A; Rogozhin, E A; Odintsova, T I; Khadeeva, N V;
Grishin, E V; Egorov, Ts A
2012-08-01
Three novel antimicrobial peptides designated ToAMP1, ToAMP2 and
ToAMP3 were purified from Taraxacum officinale flowers. Their amino
acid sequences were determined. The peptides are cationic and
cysteine-rich and consist of 38, 44 and 42 amino acid residues for
ToAMP1, ToAMP2 and ToAMP3, respectively. Importantly, according to
cysteine motifs, the peptides are representatives of two novel
previously unknown families of plant antimicrobial peptides. ToAMP1
and ToAMP2 share high sequence identity and belong to
6-Cys-containing antimicrobial peptides, while ToAMP3 is a member
of a distinct 8-Cys family. The peptides were shown to display high
antimicrobial activity both against fungal and bacterial pathogens,
and therefore represent new promising molecules for
biotechnological and medicinal applications. Crown Copyright 2012.
Published by Elsevier Inc. All rights reserved.
Novel cell penetrating peptides with multiple motifs composed of
RGD and its analogs.
PubMed
Mokhtarieh, Amir Abbas; Kim, Semi; Lee, Yunhee; Chung, Bong
Hyun; Lee, Myung Kyu
2013-03-08
Cell penetrating peptides (CPPs) have been used to transport
macromolecules into cells. Most CPPs have properties such as a
strong polycationic charge, amphipathic basic, and hydrophobicity.
In this study, we designed the peptides with multiple motifs
composed of RGD and its analogs to induce integrin-mediated
endocytosis as well as endosomal escape by forming an amphipathic
helix in acidic endosomes. These peptides were proved less toxic to
animal cells than those without acidic residues. Unexpectedly,
peptide conjugated liposomes could penetrate into cells regardless
of integrins. The replacement of all aspartic acids by glutamic
acids did not prevent the peptide-mediated liposome uptake, and the
higher basic and leucine contents enhanced the gene silencing
activity of siRNA encapsulated in the liposomes. The peptide is
considered to be a new type of CPP which can be used for drug
delivery. Copyright 2013 Elsevier Inc. All rights reserved.
Analysis of protective antigen peptide binding motifs using
bacterial display technology
NASA Astrophysics Data System (ADS)
Sarkes, Deborah A.; Dorsey, Brandi L.; Stratis-Cullum, Dimitra
N.
2015-05-01
In today's fast-paced world, a new biological threat could
emerge at any time, necessitating a prompt, reliable, inexpensive
detection reagent in each case. Combined with magnetic-activated
cell sorting (MACS), bacterial display technology makes it possible
to isolate selective, high affinity peptide reagents in days to
weeks. Utilizing the eCPX display scaffold is also a rapid way to
screen potential peptide reagents. Peptide affinity reagents for
protective antigen (PA) of the biothreat Bacillus anthracis were
previously discovered using bacterial display. Bioinformatics
analysis resulted in the consensus sequence WXCFTC. Additionally,
we have discovered PA binding peptides with a WW motif, one of
which, YGLHPWWKNAPIGQR, can pull down PA from 1% human serum. The
strength of these two motifs combined, to obtain a WWCFTC
consensus, is assessed here using Fluorescence Activated Cell
Sorting (FACS). While monitoring binding to PA, overall expression
of the display scaffold was assessed using the YPet Mona expression
control tag (YPet), and specificity was assessed by binding to
Streptavidin R-Phycoerythrin (SAPE). The importance of high YPet
binding is highlighted as many of the peptides in one of the three
replicate experiments fell below our 80% binding threshold. We
demonstrate that it is preferable to discard this experiment, due
to questionable expression of the peptide itself, than to try to
normalize for relative expression. The peptides containing the
WWCFTC consensus were of higher affinity and greater specificity
than the peptides containing the WW consensus alone, validating
further investigation to optimize known PA binders.
Characterization of a membrane protein folding motif, the Ser
zipper, using designed peptides.
PubMed
North, Benjamin; Cristian, Lidia; Fu Stowell, Xiaoran; Lear,
James D; Saven, Jeffrey G; Degrado, William F
2006-06-16
Polar residues play important roles in the association of
transmembrane helices and the stabilities of membrane proteins.
Although a single Ser residue in a transmembrane helix is unable to
mediate a strong association of the helices, the cooperative
interactions of two or more appropriately placed serine hydroxyl
groups per helix has been hypothesized to allow formation of a
"serine zipper" that can stabilize transmembrane helix association.
In particular, a heptad repeat Sera Xxx Xxx Leud Xxx Xxx Xxx (Xxx
is a hydrophobic amino acid) appears in both antiparallel helical
pairs of polytopic membrane proteins as well as the parallel
helical dimerization motif found in the murine erythropoietin
receptor. To examine the intrinsic conformational preferences of
this motif independent of its context within a larger protein, we
synthesized a peptide containing three copies of a SeraLeud heptad
motif. Computational results are consistent with the designed
peptide adopting either a parallel or antiparallel structure, and
conformational search calculations yield the parallel dimer as the
lowest energy configuration, which is also significantly more
stable than the parallel trimer. Analytical ultracentrifugation
indicated that the peptide exists in a monomer-dimer equilibrium in
dodecylphosphocholine micelles. Thiol disulfide interchange studies
showed a preference for forming parallel dimers in micelles. In
phospholipid vesicles, only the parallel dimer was formed. The
stability of the SerZip peptide was studied in vesicles prepared
from phosphatidylcholine (PC) lipids of different chain length:
POPC (C16:0C18:1 PC) and DLPC (C12:0PC). The stability was greater
in POPC, which has a good match between the length of the
hydrophobic region of the peptide and the bilayer length. Finally,
mutation to Ala of the Ser residues in the SerZip motif gave rise
to a relatively small decrease in the stability of the dimer,
indicating that packing interactions rather than hydrogen
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Structural similarities in the CPC clip motif explain
peptide-binding promiscuity between glycosaminoglycans and
lipopolysaccharides.
PubMed
Pulido, David; Rebollido-Rios, Roco; Valle, Javier; Andreu,
David; Boix, Ester; Torrent, Marc
2017-11-01
Lipopolysaccharides (LPSs) and glycosaminoglycans (GAGs) are
polymeric structures containing negatively charged disaccharide
units that bind to specialized proteins and peptides in the human
body and control fundamental processes such as inflammation and
coagulation. Surprisingly, some proteins can bind both LPSs and
GAGs with high affinity, suggesting that a cross-communication
between these two pathways can occur. Here, we explore whether GAGs
and LPSs can share common binding sites in proteins and what are
the structural determinants of this binding. We found that the
LPS-binding peptide YI12WF, derived from protein FhuA, can bind
both heparin and E. coli LPS with high affinity. Most
interestingly, mutations decreasing heparin binding in the peptide
also reduce LPS affinity. We show that such mutations involve the
CPC clip motif in the peptide, a small three-dimensional signature
required for heparin binding. Overall, we conclude that negatively
charged polysaccharide-containing polymers such as GAGs and LPSs
can compete for similar binding sites in proteins, and that the CPC
clip motif is essential to bind both ligands. Our results provide a
structural framework to explain why these polymers can
cross-interact with the same proteins and peptides and thus
contribute to the regulation of apparently unrelated processes in
the body. 2017 The Author(s).
Modeling EphB4-EphrinB2 protein-protein interaction using
flexible docking of a short linear motif.
PubMed
Ciemny, Maciej Pawel; Kurcinski, Mateusz; Blaszczyk, Maciej;
Kolinski, Andrzej; Kmiecik, Sebastian
2017-08-18
Many protein-protein interactions are mediated by a short linear
motif. Usually, amino acid sequences of those motifs are known or
can be predicted. It is much harder to experimentally characterize
or predict their structure in the bound form. In this work, we test
a possibility of using flexible docking of a short linear motif to
predict the interaction interface of the EphB4-EphrinB2 complex (a
system extensively studied for its significance in tumor
progression). In the modeling, we only use knowledge about the
motif sequence and experimental structures of EphB4-EphrinB2
complex partners. The proposed protocol enables efficient modeling
of significant conformational changes in the short linear motif
fragment during molecular docking simulation. For the docking
simulations, we use the CABS-dock method for docking fully flexible
peptides to flexible protein receptors (available as a server at
http://biocomp.chem.uw.edu.pl/CABSdock/ ). Based on the docking
result, the protein-protein complex is reconstructed and refined.
Using this novel protocol, we obtained an accurate EphB4-EphrinB2
interaction model. The results show that the CABS-dock method may
be useful as the primary docking tool in specific protein-protein
docking cases similar to EphB4-EphrinB2 complex-that is, where a
short linear motif fragment can be identified.
Deep sequencing of phage-displayed peptide libraries reveals
sequence motif that detects norovirus.
PubMed
Hurwitz, Amy M; Huang, Wanzhi; Estes, Mary K; Atmar, Robert L;
Palzkill, Timothy
2017-02-01
Norovirus infections are the leading cause of non-bacterial
gastroenteritis and result in about 21 million new cases and $2
billion in costs per year in the United States. Existing
diagnostics have limited feasibility for point-of-care
applications, so there is a clear need for more reliable, rapid,
and simple-to-use diagnostic tools in order to contain outbreaks
and prevent inappropriate treatments. In this study, a combination
of phage display technology, deep sequencing and computational
analysis was used to identify 12-mer peptides with specific binding
to norovirus genotype GI.1 virus-like particles (VLPs). After
biopanning, phage populations were sequenced and analyzed to
identify a consensus peptide motif-YRSWXP. Two 12-mer peptides
containing this sequence, NV-O-R5-3 and NV-O-R5-6, were further
characterized to evaluate the motif's functional ability to detect
VLPs and virus. Results indicated that these peptides effectively
detect GI.1 VLPs in solid-phase peptide arrays, ELISAs and dot
blots. Further, their specificity for the S-domain of the major
capsid protein enables them to detect a wide range of GI and GII
norovirus genotypes. Both peptides were able to detect virus in
norovirus-positive clinical stool samples. Overall, the work
reported here demonstrates the application of phage display coupled
with next generation sequencing and computational analysis to
uncover peptides with specific binding ability to a target protein
for diagnostic applications. Further, the reagents characterized
here can be integrated into existing diagnostic formats to detect
clinically relevant genotypes of norovirus in stool. The Author
2016. Published by Oxford University Press. All rights reserved.
For Permissions, please e-mail: [email protected].
Structural basis of HP1/PXVXL motif peptide interactions and HP1
localisation to heterochromatin
PubMed Central
Thiru, Abarna; Nietlispach, Daniel; Mott, Helen R; Okuwaki,
Mitsuru; Lyon, Debbie; Nielsen, Peter R; Hirshberg, Miriam;
Verreault, Alain; Murzina, Natalia V; Laue, Ernest D
2004-01-01
HP1 family proteins are adaptor molecules, containing two
related chromo domains that are required for chromatin packaging
and gene silencing. Here we present the structure of the chromo
shadow domain from mouse HP1 bound to a peptide containing a
consensus PXVXL motif found in many HP1 binding partners. The
shadow domain exhibits a novel mode of peptide recognition, where
the peptide binds across the dimer interface, sandwiched in a
-sheet between strands from each monomer. The structure allows us
to predict which other shadow domains bind similar PXVXL
motif-containing peptides and provides a framework for predicting
the sequence specificity of the others. We show that targeting of
HP1 to heterochromatin requires shadow domain interactions with
PXVXL-containing proteins in addition to chromo domain recognition
of Lys-9-methylated histone H3. Interestingly, it also appears to
require the simultaneous recognition of two Lys-9-methylated
histone H3 molecules. This finding implies a further complexity to
the histone code for regulation of chromatin structure and suggests
how binding of HP1 family proteins may lead to its condensation.
PMID:14765118
Non-canonical anchor motif peptides bound to MHC class I induce
cellular responses.
PubMed
Lazoura, Eliada; Lodding, Jodie; Farrugia, William; Day,
Stephanie; Ramsland, Paul A; Apostolopoulos, Vasso
2009-03-01
The major histocompatibility complex (MHC) on the surface of
antigen presenting cells functions to display peptides to the T
cell receptor (TCR). Recognition of peptide-MHC by T cells
initiates a cascade of signals, which results in the initiation of
a T cell dependent immune response. An understanding of how
peptides bind to MHC molecules is important for determining the
structural basis for T cell dependent immune responses and
facilitates the structure-based design of peptides as candidate
vaccines to elicit a specific immune response. To date, crystal
structures, immunogenicity and in vivo biological relevance have
mainly been characterized for high affinity peptide-MHC
interactions. From the crystal structures of numerous peptide-MHC
complexes it became apparent what canonical sequence features were
required for high affinity binding, which led to the ability to
predict in most instances peptides with high affinity for MHC. We
previously identified the crystal structures of non-canonical
peptides in complex with MHC class I (one bound with low affinity
and the other with high affinity, but utilizing novel peptide
anchors and MHC pockets). It is becoming increasingly evident that
other non-canonical peptides can also bind, such as long-, short-
and glyco-peptides. However, the in vivo role of non-canonical
peptides is not clear and we present here the immunogenicity of two
non-canonical peptides and their affinity when bound to MHC class
I, H2K(b). Comparison of the three-dimensional structures in
complex with MHC suggests major differences in hydrogen bonding
patterns with H2K(b), despite sharing similar binding modes, which
may account for the differences in affinity and immunogenicity.
These studies provide further evidence for the diverse range of
peptide ligands that can bind to MHC and be recognized by the TCR,
which will facilitate approaches to peptide-based vaccine
design.
Prediction of virus-host protein-protein interactions mediated
by short linear motifs.
PubMed
Becerra, Andrs; Bucheli, Victor A; Moreno, Pedro A
2017-03-09
Short linear motifs in host organisms proteins can be mimicked
by viruses to create protein-protein interactions that disable or
control metabolic pathways. Given that viral linear motif instances
of host motif regular expressions can be found by chance, it is
necessary to develop filtering methods of functional linear motifs.
We conduct a systematic comparison of linear motifs filtering
methods to develop a computational approach for predicting
motif-mediated protein-protein interactions between human and the
human immunodeficiency virus 1 (HIV-1). We implemented three
filtering methods to obtain linear motif sets: 1) conserved in
viral proteins (C), 2) located in disordered regions (D) and 3)
rare or scarce in a set of randomized viral sequences (R). The sets
C,D,R are united and intersected. The resulting sets are compared
by the number of protein-protein interactions correctly inferred
with them - with experimental validation. The comparison is done
with HIV-1 sequences and interactions from the National Institute
of Allergy and Infectious Diseases (NIAID). The number of correctly
inferred interactions allows to rank the interactions by the sets
used to deduce them: DR and C. The ordering of the sets is
descending on the probability of capturing functional interactions.
With respect to HIV-1, the sets CR, DR, CDR infer all known
interactions between HIV1 and human proteins mediated by linear
motifs. We found that the majority of conserved linear motifs in
the virus are located in disordered regions. We have developed a
method for predicting protein-protein interactions mediated by
linear motifs between HIV-1 and human proteins. The method only use
protein sequences as inputs. We can extend the software developed
to any other eukaryotic virus and host in order to find and rank
candidate interactions. In future works we will use it to explore
possible viral attack mechanisms based on linear motif mimicry.
Structure-activity relationship study on a simple cationic
peptide motif for cellular delivery of antisense peptide nucleic
acid.
PubMed
Albertshofer, Klaus; Siwkowski, Andrew M; Wancewicz, Edward V;
Esau, Christine C; Watanabe, Tanya; Nishihara, Kenji C; Kinberger,
Garth A; Malik, Leila; Eldrup, Anne B; Manoharan, Muthiah; Geary,
Richard S; Monia, Brett P; Swayze, Eric E; Griffey, Richard H;
Bennett, C Frank; Maier, Martin A
2005-10-20
Improving cellular uptake and biodistribution remains one of the
major obstacles for a successful and broad application of peptide
nucleic acids (PNAs) as antisense therapeutics. Recently, we
reported the identification and functional characterization of an
antisense PNA, which redirects splicing of murine CD40 pre-mRNA. In
this context, it was discovered that a simple octa(l-lysine)
peptide covalently linked to the PNA is capable of promoting free
uptake of the conjugate into BCL1 cells as well as primary murine
macrophages. On the basis of this peptide motif, the present study
aimed at identifying the structural features, which define
effective peptide carriers for cellular delivery of PNA. While the
structure-activity relationship study revealed some clear
correlations, only a few modifications actually led to an overall
improvement as compared to the parent octa(l-lysine) conjugate. In
a preliminary PK/tissue distribution study in healthy mice, the
parent conjugate exhibited relatively broad tissue distribution and
only modest elimination via excretion within the time frame of the
study.
A minimal length rigid helical peptide motif allows rational
design of modular surfactants
NASA Astrophysics Data System (ADS)
Mondal, Sudipta; Varenik, Maxim; Bloch, Daniel Nir; Atsmon-Raz,
Yoav; Jacoby, Guy; Adler-Abramovich, Lihi; Shimon, Linda J. W.;
Beck, Roy; Miller, Yifat; Regev, Oren; Gazit, Ehud
2017-01-01
Extensive work has been invested in the design of bio-inspired
peptide emulsifiers. Yet, none of the formulated surfactants were
based on the utilization of the robust conformation and
self-assembly tendencies presented by the hydrophobins, which
exhibited highest surface activity among all known proteins. Here
we show that a minimalist design scheme could be employed to
fabricate rigid helical peptides to mimic the rigid conformation
and the helical amphipathic organization. These designer building
blocks, containing natural non-coded -aminoisobutyric acid (Aib),
form superhelical assemblies as confirmed by crystallography and
microscopy. The peptide sequence is amenable to structural
modularity and provides the highest stable emulsions reported so
far for peptide and protein emulsifiers. Moreover, we establish the
ability of short peptides to perform the dual functions of
emulsifiers and thickeners, a feature that typically requires
synergistic effects of surfactants and polysaccharides. This work
provides a different paradigm for the molecular engineering of
bioemulsifiers.
A minimal length rigid helical peptide motif allows rational
design of modular surfactants
PubMed Central
Mondal, Sudipta; Varenik, Maxim; Bloch, Daniel Nir; Atsmon-Raz,
Yoav; Jacoby, Guy; Adler-Abramovich, Lihi; Shimon, Linda J.W.;
Beck, Roy; Miller, Yifat; Regev, Oren; Gazit, Ehud
2017-01-01
Extensive work has been invested in the design of bio-inspired
peptide emulsifiers. Yet, none of the formulated surfactants were
based on the utilization of the robust conformation and
self-assembly tendencies presented by the hydrophobins, which
exhibited highest surface activity among all known proteins. Here
we show that a minimalist design scheme could be employed to
fabricate rigid helical peptides to mimic the rigid conformation
and the helical amphipathic organization. These designer building
blocks, containing natural non-coded -aminoisobutyric acid (Aib),
form superhelical assemblies as confirmed by crystallography and
microscopy. The peptide sequence is amenable to structural
modularity and provides the highest stable emulsions reported so
far for peptide and protein emulsifiers. Moreover, we establish the
ability of short peptides to perform the dual functions of
emulsifiers and thickeners, a feature that typically requires
synergistic effects of surfactants and polysaccharides. This work
provides a different paradigm for the molecular engineering of
bioemulsifiers. PMID:28084315
Synthetic approaches to peptides containing the
L-Gln-L-Val-D(S)-Dmt motif.
PubMed
Suaifan, Ghadeer A R Y; Arafat, Tawfiq; Threadgill, Michael
D
2007-05-15
The pseudoprolines S-Dmo (5,5-dimethyl-4-oxaproline) and R-Dmt
(5,5-dimethyl-4-thiaproline) have been used to study the effects of
forcing a fully cis conformation in peptides. Synthesis of peptides
containing these (which have the same configuration as L-Pro) is
straightforward. However, synthesis of peptides containing S-Dmt is
difficult, owing to the rapid cyclisation of L-Aaa-S-Dmt amides and
esters to form the corresponding diketopiperazines (DKP); thus the
intermediacy of L-Aaa-S-Dmt amides and esters must be avoided in
the synthetic sequence. Peptides containing the
L-Gln-L-Val-D(S)-Dmt motif are particularly difficult, owing to the
insolubility of coupling partners containing Gln. Introduction of
Gln as N-Boc-pyroglutamate overcame the latter difficulty and the
dipeptide active ester BocPygValOC(6)F(5) coupled in good yield
with S-DmtOH. BocPygVal-S- DmtNH(CH(2))(2)C(6)H(4)NO(2) was
converted quantitatively to
BocGlnVal-S-DmtNH(CH(2))(2)C(6)H(4)NO(2) with ammonia,
demonstrating the utility of this approach. Two peptide derivatives
(CbzSerLysLeuGlnVal-S-DmtNH(CH(2))(2)C(6)H(4)NO(2) and
CbzSerSerLysLeuGlnVal-S- DmtNH(CH(2))(2)C(6)H(4)NO(2)) were
assembled, using these new methods of coupling a dipeptide acid
active ester with S-DmtOH and introduction of Gln as Pyg, followed
by conventional peptide couplings. The presence of the Val caused
these peptides to be cleaved very slowly by prostate-specific
antigen (PSA) at Leu Gln, rather than the expected Gln Val.
Deep sequencing of phage-displayed peptide libraries reveals
sequence motif that detects norovirus
PubMed Central
Hurwitz, Amy M.; Huang, Wanzhi; Estes, Mary K.; Atmar, Robert
L.; Palzkill, Timothy
2017-01-01
Norovirus infections are the leading cause of non-bacterial
gastroenteritis and result in about 21 million new cases and $2
billion in costs per year in the United States. Existing
diagnostics have limited feasibility for point-of-care
applications, so there is a clear need for more reliable, rapid,
and simple-to-use diagnostic tools in order to contain outbreaks
and prevent inappropriate treatments. In this study, a combination
of phage display technology, deep sequencing and computational
analysis was used to identify 12-mer peptides with specific binding
to norovirus genotype GI.1 virus-like particles (VLPs). After
biopanning, phage populations were sequenced and analyzed to
identify a consensus peptide motifYRSWXP. Two 12-mer peptides
containing this sequence, NV-O-R5-3 and NV-O-R5-6, were further
characterized to evaluate the motif's functional ability to detect
VLPs and virus. Results indicated that these peptides effectively
detect GI.1 VLPs in solid-phase peptide arrays, ELISAs and dot
blots. Further, their specificity for the S-domain of the major
capsid protein enables them to detect a wide range of GI and GII
norovirus genotypes. Both peptides were able to detect virus in
norovirus-positive clinical stool samples. Overall, the work
reported here demonstrates the application of phage display coupled
with next generation sequencing and computational analysis to
uncover peptides with specific binding ability to a target protein
for diagnostic applications. Further, the reagents characterized
here can be integrated into existing diagnostic formats to detect
clinically relevant genotypes of norovirus in stool.
PMID:28035012
Improved Bioactivity of Antimicrobial Peptides by Addition of
Amino-Terminal Copper and Nickel (ATCUN) Binding Motifs
PubMed Central
Libardo, M. Daben; Cervantes, Jorge L.; Salazar, Juan C.;
Angeles-Boza, Alfredo M.
2015-01-01
Antimicrobial peptides (AMPs) are promising candidates to help
circumvent antibiotic resistance, which is an increasing clinical
problem. Amino-terminal copper and nickel (ATCUN) binding motifs
are known to actively form reactive oxygen species (ROS) upon metal
binding. The combination of these two peptidic constructs could
lead to a novel class of dual-acting antimicrobial agents. To test
this hypothesis, a set of ATCUN binding motifs were screened for
their ability to induce ROS formation, and the most potent were
then used to modify AMPs with different modes of action. ATCUN
binding motif-containing derivatives of anoplin (GLLKRIKTLL-NH2),
pro-apoptotic peptide (PAP; KLAKLAKKLAKLAK-NH2), and sh-buforin
(RAGLQFPVGRVHRLLRK-NH2) were synthesized and found to be more
active than the parent AMPs against a panel of clinically relevant
bacteria. The lower minimum inhibitory concentration (MIC) values
for the ATCUN-anoplin peptides are attributed to the higher
pore-forming activity along with their ability to cause ROS-induced
membrane damage. The addition of the ATCUN motifs to PAP also
increases its ability to disrupt membranes. DNA damage is the major
contributor to the activity of the ATCUN-sh-buforin peptides. Our
findings indicate that the addition of ATCUN motifs to AMPs is a
simple strategy that leads to AMPs with higher antibacterial
activity and possibly to more potent, usable antibacterial agents.
PMID:24803240
Identification of an Orthogonal Peptide Binding Motif for
Biarsenical Multiuse Affinity Probes
SciTech Connect
Chen, Baowei; Cao, Haishi; Yan, Ping; Mayer, M. Uljana; Squier,
Thomas C.
2007-07-01
Biarsenical multiuse affinity probes (MAPs) complexed with
ethanedithiol (EDT) permit the selective cellular labeling of
proteins engineered with tetracysteine motifs, but are limited by
the availability of a single binding motif (i.e., CCPGCC or PG tag)
that prevents the differential labeling of co-expressed proteins.
To overcome this problem, we have used a high-throughput peptide
screen to identify an alternate binding motif (i.e., CCKACC or KA
tag), which has a similar brightness to the classical sequence upon
MAP binding, but displays altered rates and affinities of
association that permit the differential labeling of these peptide
sequences by the red probe
4,5-bis(1,3,2-dithiarsolan-2-yl)-resorufin (ReAsH-EDT2) or its
green cognate
4,5-bis(1,3,2-dithoarsolan-2-yl)fluorescein-(1,2-ethanedithiol)2
(FLAsH-EDT2). The utility of this labeling strategy was
demonstrated following the expression of PG- and KA-tagged subunits
of RNA polymerase expressed in E. coli. Specific labeling of two
subunits of RNA polymerase in cellular lysates was achieved,
whereby ReAsH-EDT2 is shown to selectively label the PG-tag on RNA
polymerase alpha subunit prior to the labeling of the KA-tag
sequence of the beta subunit of RNA polymerase with FlAsH-EDT2.
These results demonstrate the ability to selectively label multiple
individual proteins with orthogonal sequence tags in complex
cellular lystates with spectroscopically distinct MAPs, and
indicate the absolute specificity of ReAsH to target expressed
proteins with essentially no nonspecific binding interactions.
Short Arginine Motifs Drive Protein Stickiness in the
Escherichia coli Cytoplasm.
PubMed
Kyne, Ciara; Crowley, Peter B
2017-09-19
Although essential to numerous biotech applications, knowledge
of molecular recognition by arginine-rich motifs in live cells
remains limited. 1 H, 15 N HSQC and 19 F NMR spectroscopies were
used to investigate the effects of C-terminal -GR n (n = 1-5)
motifs on GB1 interactions in Escherichia coli cells and cell
extracts. While the "biologically inert" GB1 yields high-quality
in-cell spectra, the -GR n fusions with n = 4 or 5 were
undetectable. This result suggests that a tetra-arginine motif is
sufficient to drive interactions between a test protein and
macromolecules in the E. coli cytoplasm. The inclusion of a 12
residue flexible linker between GB1 and the -GR 5 motif did not
improve detection of the "inert" domain. In contrast, all of the
constructs were detectable in cell lysates and extracts, suggesting
that the arginine-mediated complexes were weak. Together these data
reveal the significance of weak interactions between short
arginine-rich motifs and the E. coli cytoplasm and demonstrate the
potential of such motifs to modify protein interactions in living
cells. These interactions must be considered in the design of (in
vivo) nanoscale assemblies that rely on arginine-rich
sequences.
Residue 81 confers a restricted C-terminal peptide binding motif
in HLA-B*44:09.
PubMed
Huyton, Trevor; Schumacher, Heike; Blasczyk, Rainer;
Bade-Doeding, Christina
2012-09-01
Knowledge about the magnitude of individual polymorphism is a
critical part in understanding the complexity of comprehensive
mismatching. HLA-B*44:09 differs from the highly frequent
HLA-B*44:02 allele by amino acid exchanges at residues 77, 80, 81,
82 and 83. We aimed to identify the magnitude of these mismatches
on the features of HLA-B*44:09 bound peptides since residues 77, 80
and 81 comprise part of the F pocket which determines sequence
specificity at the p position of the peptide. Using soluble HLA
technology we determined >200 individual (nonduplicate)
self-peptides from HLA-B*44:09 and compared their features with
that of the published peptide features of HLA-B*44:02. Both alleles
illustrate an anchor motif of E at p2. In contrast to the
C-terminal peptide binding motif of B*44:02 (W, F, Y or L),
B*44:09-derived peptides are restricted predominantly to L or F.
The source of peptides for both alleles is identical (LCL 721.221
cells) allowing us to identify 23 shared peptides. The majority of
these peptides however contained the restricted B*44:09 anchor
motif of F or L at the p position. Molecular modelling based on the
B*44:02 structure highlights that the differences of the C-terminal
peptide anchor between both alleles can be explained primarily by
the B*44:02(81Ala)>B*44:09(81Leu) polymorphism which restricts
the size of the amino acid that can be accommodated in the F pocket
of B*44:09. These results highlight that every amino acid
substitution has an impact of certain magnitude on the alleles
function and demonstrate how surrounding residues orchestrate
peptide specificity.
Using oriented peptide array libraries to evaluate
methylarginine-specific antibodies and arginine methyltransferase
substrate motifs.
PubMed
Gayatri, Sitaram; Cowles, Martis W; Vemulapalli, Vidyasiri;
Cheng, Donghang; Sun, Zu-Wen; Bedford, Mark T
2016-06-24
Signal transduction in response to stimuli relies on the
generation of cascades of posttranslational modifications that
promote protein-protein interactions and facilitate the assembly of
distinct signaling complexes. Arginine methylation is one such
modification, which is catalyzed by a family of nine protein
arginine methyltransferases, or PRMTs. Elucidating the substrate
specificity of each PRMT will promote a better understanding of
which signaling networks these enzymes contribute to. Although many
PRMT substrates have been identified, and their methylation sites
mapped, the optimal target motif for each of the nine PRMTs has not
been systematically addressed. Here we describe the use of Oriented
Peptide Array Libraries (OPALs) to methodically dissect the
preferred methylation motifs for three of these enzymes - PRMT1,
CARM1 and PRMT9. In parallel, we show that an OPAL platform with a
fixed methylarginine residue can be used to validate the
methyl-specific and sequence-specific properties of antibodies that
have been generated against different PRMT substrates, and can also
be used to confirm the pan nature of some methylarginine-specific
antibodies.
New potent and selective v3 integrin ligands: Macrocyclic
peptides containing RGD motif synthesized by sortase A-mediated
ligation.
PubMed
Wu, Zhimeng; Cheng, Xiaozhong; Hong, Haofei; Zhao, Xinrui; Zhou,
Zhifang
2017-05-01
Three 14-mer macrocyclic peptides 1-3 containing mono-, di- and
tri-RGD structure motif were designed and synthesized by sortase
A-mediated ligation in good yields. The results of in intro
cell-based biological assays indicated that linear peptide 5 and
macrocyclic peptide 1, containing di-RGD and mono-RGD motif
respectively, showed remarkable potency and selectivity to v3
integrin. Copyright 2017 Elsevier Ltd. All rights reserved.
Expression of conformationally constrained adhesion peptide in
an antibody CDR loop and inhibition of natural killer cell
cytotoxic activity by an antibody antigenized with the RGD
motif.
PubMed
Zanetti, M; Filaci, G; Lee, R H; del Guercio, P; Rossi, F;
Bacchetta, R; Stevenson, F; Barnaba, V; Billetta, R
1993-11-01
We report that an antibody engineered to express three
Arg-Gly-Asp (RGD) repeats in the third complementarity-determining
region of the heavy chain (antigenized antibody) efficiently
inhibits the lysis of human erythroleukemia K-562 cells by natural
killer (NK) cells. Synthetic peptides containing RGD did not
inhibit. Inhibition was specific for the (RGD)3-containing loop and
required simultaneous occupancy of the Fc receptor (CD16) on
effector cells. The antigenized antibody inhibited other forms of
cytotoxicity mediated by NK cells but not cytotoxicity mediated by
major histocompatibility complex-restricted cytotoxic T lymphocytes
(CTL). A three-dimensional model of the engineered antibody loop
shows the structure and physicochemical characteristics probably
required for the ligand activity. The results indicate that an RGD
motif is involved in the productive interaction between NK and
target cells. Moreover, they show that peptide expression in the
hypervariable loops of an antibody molecule is an efficient
procedure for stabilizing oligopeptides within a limited spectrum
of tertiary structures. This is a new approach towards imparting
ligand properties to antibody molecules and can be used to study
the biological function and specificity of short peptide motifs,
including those involved in cell adhesion.
Osteopontin Peptide Icosamer Containing RGD and SLAYGLR Motifs
Enhances the Motility and Phagocytic Activity of Microglia.
PubMed
Kim, Il-Doo; Lee, Hahnbie; Jin, Yin-Chuan; Lee, Ja-Kyeong
2017-12-01
Osteopontin (OPN) is a secreted glycoprotein that is expressed
in various tissues, including brain, and mediates a wide range of
cellular activities. In a previous study, the authors observed the
robust neuroprotective effects of recombinant OPN and of RGD and
SLAYGLR-containing OPN-peptide icosamer (OPNpt20) in an animal
model of transient focal ischemia, and demonstrated
anti-inflammatory and pro-angiogenic effects of OPNpt20 in the
postischemic brain. In the present study, we investigated the
effects of OPNpt20 on the motility and phagocytic activity of BV2
cells (a microglia cell line). F-actin polymerization and cell
motility were significantly enhanced in OPNpt20-treated BV2 cells,
and numbers of filopodia-like processes increased and
lamellipodia-like structures enlarged and thickened. In addition,
treatment of cells with either of three mutant OPN icosamers
containing mutation within RGD, SLAY, or RGDSLAY showed that the
RGD and SLAY motifs of OPNpt20 play critical roles in the
enhancement of cell motility, and the interaction between exogenous
OPNpt20 and endogenous v and 4 integrin and the activations of FAK,
Erk, and Akt signaling pathways were found to be involved in the
OPNpt20-mediated induction of cell motility. Furthermore,
phagocytic activity of microglia was also significantly enhanced by
OPNpt20 in a RGD and SLAY dependent manner. These results indicate
OPNpt20 containing RGD and SLAY motifs triggers microglial motility
and phagocytic activity and OPNpt20-integrin mediated signaling
plays a critical role in these activities.
QSLiMFinder: improved short linear motif prediction using
specific query protein data.
PubMed
Palopoli, Nicolas; Lythgow, Kieren T; Edwards, Richard J
2015-07-15
The sensitivity of de novo short linear motif (SLiM) prediction
is limited by the number of patterns (the motif space) being
assessed for enrichment. QSLiMFinder uses specific query protein
information to restrict the motif space and thereby increase the
sensitivity and specificity of predictions. QSLiMFinder was
extensively benchmarked using known SLiM-containing proteins and
simulated protein interaction datasets of real human proteins.
Exploiting prior knowledge of a query protein likely to be involved
in a SLiM-mediated interaction increased the proportion of true
positives correctly returned and reduced the proportion of datasets
returning a false positive prediction. The biggest improvement was
seen if a short region of the query protein flanking the
interaction site was known. All the tools and data used in this
study, including QSLiMFinder and the SLiMBench benchmarking
software, are freely available under a GNU license as part of
SLiMSuite, at: http://bioware.soton.ac.uk. The Author 2015.
Published by Oxford University Press.
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Short Laminin Peptide for Improved Neural Stem Cell Growth
PubMed Central
Li, Xiaowei; Liu, Xiaoyan; Josey, Benjamin; Chou, C. James; Tan,
Yu; Zhang, Ning
2014-01-01
Human neural stem/progenitor cells (hNSCs) are very difficult to
culture and require human or animal source extracellular matrix
molecules, such as laminin or collagen type IV, to support
attachment and to regulate their survival and proliferation. These
extracellular matrix molecules are difficult to purify from human
or animal tissues, have high batch-to-batch variability, and may
cause an immune response if used in clinical applications. Although
several laminin- and collagen IV-derived peptides are commercially
available, they do not support long-term hNSC attachment and
growth. To solve this problem, we developed a novel peptide
sequence with only 12 amino acids based on the Ile-Lys-Val-Ala-Val,
or IKVAV, sequence:
Ac-Cys-Cys-Arg-Arg-Ile-Lys-Val-Ala-Val-Trp-Leu-Cys. This short
peptide sequence, similar to tissue-derived full laminin molecules,
supported hNSCs to attach and proliferate to confluence for
continuous passage and subculture. This short peptide also directed
hNSCs to differentiate into neurons. When conjugated to
poly(ethylene glycol) hydrogels, this short peptide benefited hNSC
attachment and proliferation on the surface of hydrogels and
promoted cell migration inside the hydrogels with maximum
enhancement at a peptide density of 10 M. This novel short peptide
shows great promise in artificial niche development for supporting
hNSC culture in vitro and in vivo and for promoting hNSC
transplantation in future clinical therapy. PMID:24692587
Discovering short linear protein motif based on selective
training of profile hidden Markov models.
PubMed
Song, Tao; Gu, Hong
2015-07-21
Short linear motifs (SLiMs) in proteins are relatively
conservative sequence patterns within disordered regions of
proteins, typically 3-10 amino acids in length. They play an
important role in mediating protein-protein interactions.
Discovering SLiMs by computational methods has attracted more and
more attention, most of which were based on regular expressions and
profiles. In this paper, a de novo motif discovery method was
proposed based on profile hidden Markov models (HMMs), which can
not only provide the emission probabilities of amino acids in the
defined positions of SLiMs, but also model the undefined positions.
We adopted the ordered region masking and the relative local
conservation (RLC) masking to improve the signal to noise ratio of
the query sequences while applying evolutionary weighting to make
the important sequences in evolutionary process get more attention
by the selective training of profile HMMs. The experimental results
show that our method and the profile-based method returned
different subsets within a SLiMs dataset, and the performance of
the two approaches are equivalent on a more realistic discovery
dataset. Profile HMM-based motif discovery methods complement the
existing methods and provide another way for SLiMs analysis.
Copyright 2015 Elsevier Ltd. All rights reserved.
Design and surface immobilization of short anti-biofilm
peptides.
PubMed
Mishra, Biswajit; Lushnikova, Tamara; Golla, Radha M; Wang,
Xiuqing; Wang, Guangshun
2017-02-01
Short antimicrobial peptides are essential to keep us healthy
and their lasting potency can inspire the design of new types of
antibiotics. This study reports the design of a family of
eight-residue tryptophan-rich peptides (TetraF2W) obtained by
converting the four phenylalanines in temporin-SHf to tryptophans.
The temporin-SHf template was identified from the antimicrobial
peptide database (http://aps.unmc.edu/AP). Remarkably, the double
arginine variant (TetraF2W-RR) was more effective in killing
methicillin-resistant Staphylococcus aureus (MRSA) USA300, but less
cytotoxic to human skin HaCat and kidney HEK293 cells, than the
lysine-containing dibasic combinations (KR, RK and KK). Killing
kinetics and fluorescence spectroscopy suggest membrane targeting
of TetraF2W-RR, making it more difficult for bacteria to develop
resistance. Because established biofilms on medical devices are
difficult to remove, we chose to covalently immobilize TetraF2W-RR
onto the polyethylene terephthalate (PET) surface to prevent
biofilm formation. The successful surface coating of the peptide is
supported by FT-IR and XPS spectroscopies, chemical quantification,
and antibacterial assays. This peptide-coated surface indeed
prevented S. aureus biofilm formation with no cytotoxicity to human
cells. In conclusion, TetraF2W-RR is a short Trp-rich peptide with
demonstrated antimicrobial and anti-biofilm potency against MRSA in
both the free and immobilized forms. Because these short peptides
can be synthesized cost effectively, they may be developed into new
antimicrobial agents or used as surface coating compounds. It is
stunning that the total deaths due to methicillin-resistant
Staphylococcus aureus (MRSA) infection are comparable to
AIDS/HIV-1, making it urgent to explore new possibilities. This
study deals with this problem by two strategies. First, we have
designed a family of novel antimicrobial peptides with merely eight
amino acids, making it cost effective for chemical synthesis
High-sensitivity HLA class I peptidome analysis enables a
precise definition of peptide motifs and the identification of
peptides from cell lines and patients' sera.
PubMed
Ritz, Danilo; Gloger, Andreas; Weide, Benjamin; Garbe, Claus;
Neri, Dario; Fugmann, Tim
2016-05-01
The characterization of peptides bound to human leukocyte
antigen (HLA) class I is of fundamental importance for
understanding CD8+ T cell-driven immunological processes and for
the development of immunomodulatory therapeutic strategies.
However, until now, the mass spectrometric analysis of HLA-bound
peptides has typically required billions of cells, still resulting
in relatively few high-confidence peptide identifications.
Capitalizing on the recent developments in mass spectrometry and
bioinformatics, we have implemented a methodology for the efficient
recovery of acid-eluted HLA peptides after purification with the
pan-reactive antibody W6/32 and have identified a total of 27 862
unique peptides with high confidence (1% false discovery rate) from
five human cancer cell lines. More than 93% of the identified
peptides were eight to 11 amino acids in length and contained
signatures that were in excellent agreement with published HLA
binding motifs. Furthermore, by purifying soluble HLA class I
complexes (sHLA) from sera of melanoma patients, up to 972
high-confidence peptides could be identified, including
melanoma-associated antigens already described in the literature.
Knowledge of the HLA class I peptidome should facilitate multiplex
tetramer technology-based characterization of T cells, and allow
the development of patient selection, stratification and
immunomodulatory therapeutic strategies. 2016 WILEY-VCH Verlag GmbH
& Co. KGaA, Weinheim.
Galectin-1-asialofetuin interaction is inhibited by peptides
containing the tyr-xxx-tyr motif acting on the glycoprotein.
PubMed
Wber, Edit; Hetnyi, Anasztzia; Vczi, Balzs; Szolnoki, Eva;
Fajka-Boja, Roberta; Tubak, Vilmos; Monostori, Eva; Martinek, Tams
A
2010-01-25
Galectin-1 (Gal-1), a ubiquitous beta-galactoside-binding
protein expressed by various normal and pathological tissues, has
been implicated in cancer and autoimmune/inflammatory diseases in
consequence of its regulatory role in adhesion, cell viability,
proliferation, and angiogenesis. The functions of Gal-1 depend on
its affinity for beta-galactoside-containing glycoconjugates;
accordingly, the inhibition of sugar binding blocks its functions,
hence promising potential therapeutic tools. The Tyr-Xxx-Tyr
peptide motifs have been reported to be glycomimetic sequences,
mainly on the basis of their inhibitory effect on the
Gal-1-asialofetuin (ASF) interaction. However, the results
regarding the efficacy of the Tyr-Xxx-Tyr motif as a glycomimetic
inhibitor are still controversial. The present STD and trNOE NMR
experiments reveal that the Tyr-Xxx-Tyr peptides studied do not
bind to Gal-1, whereas their binding to ASF is clearly detected.
(15)N,(1)H HSQC titrations with (15)N-labeled Gal-1 confirm the
absence of any peptide-Gal-1 interaction. These data indicate that
the Tyr-Xxx-Tyr peptides tested in this work are not glycomimetics
as they interact with ASF via an unrevealed molecular linkage.
Machine learning study of classifiers trained with
biophysiochemical properties of amino acids to predict fibril
forming Peptide motifs.
PubMed
Kumaran Nair, Smitha Sunil; Subba Reddy, N V; Hareesha, K S
2012-09-01
It is important to understand the cause of amyloid illnesses by
predicting the short protein fragments capable of forming
amyloid-like fibril motifs aiding in the discovery of
sequence-targeted anti-aggregation drugs. It is extremely desirable
to design computational tools to provide affordable in silico
predictions owing to the limitations of molecular techniques for
their identification. In this research article, we tried to study,
from a machine learning perspective, the performance of several
machine learning classifiers that use heterogenous features based
on biochemical and biophysical properties of amino acids to
discriminate between amyloidogenic and non-amyloidogenic regions in
peptides. Four conventional machine learning classifiers namely
Support Vector Machine, Neural network, Decision tree and Random
forest were trained and tested to find the best classifier that
fits the problem domain well. Prior to classification, novel
implementations of two biologically-inspired feature optimization
techniques based on evolutionary algorithms and methodologies that
mimic social life and a multivariate method based on projection are
utilized in order to remove the unimportant and uninformative
features. Among the dimenionality reduction algorithms considered
under the study, prediction results show that algorithms based on
evolutionary computation is the most effective. SVM best suits the
problem domain in its fitment among the classifiers considered. The
best classifier is also compared with an online predictor to
evidence the equilibrium maintained between true positive rates and
false positive rates in the proposed classifier. This exploratory
study suggests that these methods are promising in providing
amyloidogenity prediction and may be further extended for
large-scale proteomic studies.
Identification of a conformational heparin-recognition motif on
the peptide hormone secretin: key role for cell surface
binding.
PubMed
Quittot, No; Nguyen, Phuong Trang; Nere, Armelle Tchoumi;
Lussier, Marc P; Bourgault, Steve
2017-06-26
Secretin is a peptide hormone that exerts pleiotropic
physiological functions by specifically binding to its cognate
membrane-bound receptor. The membrane catalysis model of
peptide-receptor interactions states that soluble peptidic ligands
initially interact with the plasma membrane. This interaction
increases the local concentration and structures the peptide,
enhancing the rate of receptor binding. However, this model does
not consider the dense network of glycosaminoglycans (GAGs) at the
surface of eukaryotic cells. These sulfated polysaccharide chains
are known to sequester numerous proteic signaling molecules. In the
present study, we evaluated the interaction between the peptide
hormone secretin and sulfated GAGs and its contribution to cell
surface binding. Using GAG-deficient cells and competition
experiments with soluble GAGs, we observed by confocal microscopy
and flow cytometry that GAGs mediate the sequestration of secretin
at the cell surface. Isothermal titration calorimetry and surface
plasmon resonance revealed that secretin binds to heparin with
dissociation constants ranging between 0.9 and 4M. By designing
secretin derivatives with a restricted conformational ensemble, we
observed that this interaction is mediated by the presence of a
specific conformational GAG-recognition motif that decorates the
surface of the peptide upon helical folding. The present study
identifies secretin as a novel GAG-binding polypeptide and opens
new research direction on the functional role of GAGs in the
biology of secretin. 2017 The Author(s); published by Portland
Press Limited on behalf of the Biochemical Society.
FOXP in Tetrapoda: Intrinsically Disordered Regions, Short
Linear Motifs and their evolutionary significance.
PubMed
Viscardi, Lucas Henriques; Tovo-Rodrigues, Luciana; Par, Pamela;
Fagundes, Nelson Jurandi Rosa; Salzano, Francisco Mauro;
Paixo-Crtes, Vanessa Rodrigues; Bau, Claiton Henrique Dotto;
Bortolini, Maria Ctira
2017-01-01
The FOXP subfamily is probably the most extensively
characterized subfamily of the forkhead superfamily, playing
important roles in development and homeostasis in vertebrates.
Intrinsically disorder protein regions (IDRs) are protein segments
that exhibit multiple physical interactions and play critical roles
in various biological processes, including regulation and
signaling. IDRs in proteins may play an important role in the
evolvability of genetic systems. In this study, we analyzed 77
orthologous FOXP genes/proteins from Tetrapoda, regarding protein
disorder content and evolutionary rate. We also predicted the
number and type of short linear motifs (SLIMs) in the IDRs. Similar
levels of protein disorder (approximately 70%) were found for
FOXP1, FOXP2, and FOXP4. However, for FOXP3, which is shorter in
length and has a more specific function, the disordered content was
lower (30%). Mammals showed higher protein disorders for FOXP1 and
FOXP4 than non-mammals. Specific analyses related to linear motifs
in the four genes showed also a clear differentiation between FOXPs
in mammals and non-mammals. We predicted for the first time the
role of IDRs and SLIMs in the FOXP gene family associated with
possible adaptive novelties within Tetrapoda. For instance, we
found gain and loss of important phosphorylation sites in the Homo
sapiens FOXP2 IDR regions, with possible implication for the
evolution of human speech.
FOXP in Tetrapoda: Intrinsically Disordered Regions, Short
Linear Motifs and their evolutionary significance
PubMed Central
Viscardi, Lucas Henriques; Tovo-Rodrigues, Luciana; Par, Pamela;
Fagundes, Nelson Jurandi Rosa; Salzano, Francisco Mauro;
Paixo-Crtes, Vanessa Rodrigues; Bau, Claiton Henrique Dotto;
Bortolini, Maria Ctira
2017-01-01
Abstract The FOXP subfamily is probably the most extensively
characterized subfamily of the forkhead superfamily, playing
important roles in development and homeostasis in vertebrates.
Intrinsically disorder protein regions (IDRs) are protein segments
that exhibit multiple physical interactions and play critical roles
in various biological processes, including regulation and
signaling. IDRs in proteins may play an important role in the
evolvability of genetic systems. In this study, we analyzed 77
orthologous FOXP genes/proteins from Tetrapoda, regarding protein
disorder content and evolutionary rate. We also predicted the
number and type of short linear motifs (SLIMs) in the IDRs. Similar
levels of protein disorder (approximately 70%) were found for
FOXP1, FOXP2, and FOXP4. However, for FOXP3, which is shorter in
length and has a more specific function, the disordered content was
lower (30%). Mammals showed higher protein disorders for FOXP1 and
FOXP4 than non-mammals. Specific analyses related to linear motifs
in the four genes showed also a clear differentiation between FOXPs
in mammals and non-mammals. We predicted for the first time the
role of IDRs and SLIMs in the FOXP gene family associated with
possible adaptive novelties within Tetrapoda. For instance, we
found gain and loss of important phosphorylation sites in the Homo
sapiens FOXP2 IDR regions, with possible implication for the
evolution of human speech. PMID:28257525
Identification of Short Hydrophobic Cell-Penetrating Peptides
for Cytosolic Peptide Delivery by Rational Design.
PubMed
Schmidt, Samuel; Adjobo-Hermans, Merel J W; Kohze, Robin;
Enderle, Thilo; Brock, Roland; Milletti, Francesca
2017-02-15
Cell-penetrating peptides (CPPs) enhance the cellular uptake of
membrane-impermeable molecules. Most CPPs are highly cationic,
potentially increasing the risk of toxic side effects and leading
to accumulation in organs such as the liver. As a consequence,
there is an unmet need for less cationic CPPs. However, design
principles for effective CPPs are still missing. Here, we
demonstrate a design principle based on a classification of
peptides according to accumulated side-chain polarity and
hydrophobicity. We show that in comparison to randomly selected
peptides, CPPs cover a distinct parameter space. We designed
peptides of only six to nine amino acids with a maximum of three
positive charges covering this property space. All peptides were
tested for cellular uptake and subcellular distribution. Following
an initial round of screening we enriched the collection with short
and hydrophobic peptides and introduced d-amino acid substitutions
and lactam bridges which increased cell uptake, in particular for
long-term incubation. Using a GFP complementation assay, for the
most active peptides we demonstrate cytosolic delivery of a
biologically active cargo peptide.
An unusual structural motif of antimicrobial peptides containing
end-to-end macrocycle and cystine-knot disulfides
PubMed Central
Tam, James P.; Lu, Yi-An; Yang, Jin-Long; Chiu, Kou-Wei
1999-01-01
Four macrocyclic cystine-knot peptides of 2931 residues, kalata,
circulin A and B (CirA and CirB), and cyclopsychotride, have been
isolated from coffee plants but have undetermined physiological
functions. These macrocycles and 10 of their analogs prepared by
chemical synthesis were tested against nine strains of microbes.
Kalata and CirA were specific for the Gram-positive Staphylococcus
aureus with a minimum inhibition concentration of 0.2 M. They were
relatively ineffective against Gram-negative bacteria such as
Escherichia coli and Pseudomonas aeruginosa. However, CirB and
cyclopsychotride were active against both Gram-positive and
Gram-negative bacteria. In particular, CirB showed potent activity
against E. coli with a minimum inhibitory concentration of 0.41 M.
All four cyclic peptides were moderately active against two strains
of fungi, Candida kefyr and Candida tropicalis, but were inactive
against Candida albicans. These macrocycles are cytotoxic and lysed
human red blood cell with a lethal dose 50% of 400 M. Modifying the
Arg residue in kalata with a keto aldehyde significantly reduced
its activity against S. aureus whereas blocking the arg in CirA
produced no significant effect. The two-disulfide variants and
their scrambled disulfide isomers exhibited antimicrobial profiles
and potency similar to their native peptides. However, in high-salt
assays (100 mM NaCl), few of these macrocyclic peptides, natives or
analogs, retained antimicrobial activity. These results show that
the macrocyclic peptides possess specific and potent antimicrobial
activity that is salt-dependent and that their initial interactions
with the microbial surfaces may be electrostatic, an effect
commonly found in defensin antimicrobial peptides. Furthermore,
their end-to-end cyclic structure with a cystine-knot motif
represents a molecular structure of antimicrobials and may provide
a useful template for the design of novel peptide antibiotics.
PMID:10430870
Comprehensive Identification of Glycated Peptides and Their
Glycation Motifs in Plasma and Erythrocytes of Control and Diabetic
Subjects
SciTech Connect
Zhang, Qibin; Monroe, Matthew E.; Schepmoes, Athena A.
2011-07-01
Non-enzymatic glycation of proteins is implicated in diabetes
mellitus and its related complications. In this report, we extend
our previous development and refinement of proteomics-based methods
for the analysis of non-enzymatically glycated proteins to
comprehensively identify glycated proteins in normal and diabetic
human plasma and erythrocytes. Using immunodepletion, enrichment,
and fractionation strategies, we identified 7749 unique glycated
peptides, corresponding to 3742 unique glycated proteins.
Semi-quantitative comparisons revealed a number of proteins with
glycation levels significantly increased in diabetes relative to
control samples and that erythrocyte proteins are more extensively
glycated than plasma proteins. A glycation motif analysis revealed
amino acidsmore that are favored more than others in the protein
primary structures in the vicinity of the glycation sites in both
sampl
