The chemokine CXCL1/MGSA plays a pivotal role in the host immune response by recruiting and activating neutrophils for microbial killing at the tissue site. CXCL1 exists reversibly as monomers and dimers, and mediates its function by binding glycosaminoglycans (GAG) and CXCR2 receptor. We recently showed that both monomers and dimers are potent CXCR2 agonists, the dimer is the high-affinity GAG ligand, lysine and arginine residues located in two non-overlapping domains mediate GAG interactions, and there is extensive overlap between GAG and receptor-binding domains. To understand how these structural properties influence in vivo function, we characterized peritoneal neutrophil recruitment of a trapped monomer and trapped dimer and a panel of WT lysine/arginine to alanine mutants. Monomers and dimers were active, but WT was more active indicating synergistic interactions promote recruitment. Mutants from both domains showed reduced GAG heparin binding affinities and reduced neutrophil recruitment, providing compelling evidence that both GAG-binding domains mediate in vivo trafficking. Further, mutant of a residue that is involved in both GAG binding and receptor signaling showed the highest reduction in recruitment. We conclude that GAG interactions and receptor activity of CXCL1 monomers and dimers are fine-tuned to regulate neutrophil trafficking for successful resolution of tissue injury.
Toxicity
challenges by antifungal arsenals and emergence of multidrug
resistance scenario has posed a serious threat to global community.
To cope up with this alarming situation, phytoactive molecules are
richest, safest, and most effective source of broad spectrum antimicrobial
compounds. In the present investigation, six phytoactive molecules
[cinnamaldehyde (CIN), epigallocatechin, vanillin, eugenol (EUG),
furanone, and epigallocatechin gallate] were studied against
Candida glabrata
and its clinical isolates. Among
these, CIN and EUG which are active components of cinnamon and clove
essential oils, respectively, exhibited maximum inhibition against
planktonic growth of
C. glabrata
at
a concentration of 64 and 128 μg mL
–1
, respectively.
These two molecules effectively inhibited and eradicated approximately
80% biofilm of
C. glabrata
and its
clinical isolates from biomaterials. CIN and EUG increased reactive
oxygen species generation, cell lysis, and ergosterol content in plasma
membrane and reduced virulence attributes (phospholipase and proteinase)
as well as catalase activity of
C. glabrata
cells. Reduction of mitochondrial membrane potential with increased
release of cytochrome
c
from mitochondria to cytosol
indicated initiation of early apoptosis in CIN- and EUG-treated
C. glabrata
cells. Transcriptional analysis showed
that multidrug transporter (
CDR1
) and ergosterol
biosynthesis genes were downregulated in the presence of CIN, while
getting upregulated in EUG-treated cells. Interestingly, genes such
as 1,3-β-glucan synthase (
FKS1
), GPI-anchored
protein (
KRE1
), and sterol importer (
AUS1
) were downregulated upon treatment of CIN/EUG. These results provided
molecular-level insights about the antifungal mechanism of CIN and
EUG against
C. glabrata
including its
resistant clinical isolate. The current data established that CIN
and EUG can be potentially formulated in new antifungal strategies.
Background: Glycosaminoglycan (GAG)-chemokine dimer interactions regulate neutrophil trafficking, but the molecular basis underlying their interactions is not well understood. Results: NMR studies of murine CXCL1 indicate that heparin spans the dimer interface and enhances its structural integrity and stability. Conclusion: Heparin binding modulates multiple structural properties of the chemokine dimer. Significance: This study provides novel structural insights into how chemokine dimers orchestrate neutrophil recruitment.
Proteins that exist in monomer-dimer equilibrium can be found in all organisms ranging from bacteria to humans; this facilitates fine-tuning of activities from signaling to catalysis. However, studying the structural basis of monomer function that naturally exists in monomer-dimer equilibrium is challenging, and most studies to date on designing monomers have focused on disrupting packing or electrostatic interactions that stabilize the dimer interface. In this study, we show that disrupting backbone H-bonding interactions by substituting dimer interface β-strand residues with proline (Pro) results in fully folded and functional monomers, by exploiting proline's unique feature, the lack of a backbone amide proton. In interleukin-8, we substituted Pro for each of the three residues that form H-bonds across the dimer interface β-strands. We characterized the structures, dynamics, stability, dimerization state, and activity using NMR, molecular dynamics simulations, fluorescence, and functional assays. Our studies show that a single Pro substitution at the middle of the dimer interface β-strand is sufficient to generate a fully functional monomer. Interestingly, double Pro substitutions, compared to single Pro substitution, resulted in higher stability without compromising native monomer fold or function. We propose that Pro substitution of interface β-strand residues is a viable strategy for generating functional monomers of dimeric, and potentially tetrameric and higher-order oligomeric proteins.
The chemokine CXCL5 is selectively expressed in highly specialized cells such as epithelial type II cells in the lung and white adipose tissue macrophages in muscle, where it mediates diverse functions from combating microbial infections by regulating neutrophil trafficking to promoting obesity by inhibiting insulin signaling. Currently very little is known regarding the structural basis of how CXCL5 mediates its novel functions. Towards this missing knowledge, we have solved the solution structure of the CXCL5 dimer by NMR spectroscopy. CXCL5 is a member of a subset of seven CXCR2-activating chemokines (CAC) that are characterized by the highly conserved ELR motif in the N-terminal tail. The structure shows that CXCL5 adopts the typical chemokine fold, but also reveals several distinct differences in the 30 s loop and N-terminal residues; not surprisingly, crosstalk between N-terminal and 30 s loop residues have been implicated as a major determinant of receptor activity. CAC function also involves binding to highly sulfated glycosaminoglycans (GAG), and the CXCL5 structure reveals a distinct distribution of positively charged residues, suggesting that differences in GAG interactions also influence function. The availability of the structure should now facilitate the design of experiments to better understand the molecular basis of various CXCL5 functions, and also serve as a template for the design of inhibitors for use in a clinical setting.
Recent advances in
the field of biomaterials and an ever-growing
need to curb the alarming rate of pollution levels have led to the
utilization of biodegradable waste to fabricate sustainable materials
with tunable properties. The current study investigated the growth
kinetics and morphology of Pleurotus ostreatus (P. ostreatus) mycelium grown on different agricultural
wastes such as wheat bran, sugarcane, sawdust, and the mixture of
these substrates. Further, it delineated the fabrication process of
biodegradable “bioblocks” from such agricultural waste
using a green synthesis approach and mycelium P. ostreatus as a natural adhesive material. The fabricated bioblocks showed
excellent thermal stability, hydrophobic properties, and mechanical
strength. The compressive strength of these bioblocks was approximately
6.0–7.5 N/mm2, which is 5–6 times higher
than that of the routinely used polystyrene packaging material. These
properties of the bioblocks render them fit to replace the non-biodegradable
materials that are commonly used in packaging applications, wall paneling,
and filtration of toxic wastes.
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