What befalls the proteins and water in a living cell when the cell dies?

The solvency of solutes of varying molecular size in the intracellular water of freshly-killed Ehrlich carcinoma cells fits the same theoretical curve that describes the solvency of similar solutes in a 36% solution of native bovine hemoglobin--a protein found only in red blood cells and making up 97.3% of the red cell's total intracellular proteins. The merging of the two sets of data confirms the prediction of the AI Hypothesis that key intracellular protein(s) in dying cells undergo(es) a transition from: (1) one in which the polypeptide NHCO groups assume a fully-extended conformation with relatively strong power of polarizing and orienting the bulk-phase water in multilayers; to (2) one in which most of the polypeptide NHCO groups are engaged in alpha-helical and other "introvert" conformations (see below for definition) with much weaker power in polarizing-orienting multilayers of bulk-phase water. This concordance of the two sets of data also shows that what we now call native hemoglobin--supposedly denoting hemoglobin found in its natural state in living red blood cells--, in fact, more closely resembles the water-polarizing, and -orienting intracellular proteins in dead cells. Although in the dead Ehrlich carcinoma cells as well as in the 36% solution of native hemoglobin, much of the protein's polypeptide NHCO groups are engaged in alpha-helical and other "introvert" conformation (Perutz 1969; Weissbluth 1974), both systems produce a weak but nonetheless pervasive and "long-range" water polarization and orientation. It is suggested that in both the dead Ehrlich carcinoma ascites cells and in the 36% native bovine hemoglobin solution, enough polypeptide NHCO groups assume the fully-extended conformation to produce the weak but far-reaching multilayer water polarization and orientation observed.     

One cell–one immunoglobin. Origin of limited heterogeneity of myeloma proteins

Plasma-cell tumour 5563 forms a single molecular species of immunoglobulin IgG(2)a, i.e. one variant of heavy chain and one variant of light chain. The molecules formed are labile and undergo alterations in charge properties, which rapidly lead to heterogeneity of the myeloma protein after synthesis. The single immunoglobulin species originally formed is found only after the shortest time-intervals tested, i.e. 10min incubation. Two types of changes in charge properties take place: (1) The originally formed protein (component o) is converted via an intermediate o' into the most basic form of 5563 myeloma protein found in serum (component a). Charge differences between these components are suppressed at pH8.9, but can be studied by chromatography at pH6.5 or by analysis of isoelectric points by isoelectric focusing in polyacrylamide gel. The conversion of components o and o' into component a apparently commences soon after assembly of the molecules and proceeds to completion extracellularly. (2) The second type of charge difference that distinguishes components a, b, c and d is exhibited over the pH range 6.0-8.9, but not at acid pH, and has been studied by electrophoresis at pH8.9, by chromatography and by isoelectric focusing. Conversion of component a into components b, c, d and e is only partial so that all five components can be found at decreasing concentrations in serum. Both types of charge alteration can be effected in vitro in the presence of serum, with optimum pH8.0. None of the charge differences could be attributed to the secretion process, since a component with the same isoelectric point as component o was found in secreted myeloma protein (1h). We have found no evidence to support the idea that the first type of change from component o to component a is due to ring formation of N-terminal [(14)C]glutamine into pyrrolid-2-one-5-carboxylic acid; however, our findings do not exclude this process happening very rapidly to a precursor of component o, possibly the polypeptide chain during or immediately after synthesis. In studying this point we noted that not only the heavy chains but also the kappa-type light chain of mouse 5563 myeloma protein have a blocked N-terminus.     

Involvement of cortactin and phosphotyrosine proteins in cell–cell contact formation in cultured bovine corneal endothelial cells

Phosphotyrosine proteins involvement, particularly cortactin, was studied in cell–cell contacts of cultured bovine corneal endothelial (BCE) cells. These proteins, including α-catenin, vinculin and cortactin, are localized at cell–cell contacts separate from the cortical actin ring. Approximately 50% of cortactin isoforms p80 and p85 were associated with the Triton-insoluble fraction while phosphotyrosine proteins were in the soluble fraction. Disruption of cell–cell contacts by EDTA treatment was associated with a decrease in cortactin isoforms p80 (26%) and p85 (57%). Cortactin isoform p85 was phosphorylated at Y⁴⁶⁶, expressed in reattaching cells and associated with the Triton-soluble fraction, whereas cortactin isoform p80 was phosphorylated at Y⁴²¹ and associated with the Triton-insoluble fraction. In sub-confluent cultures, pY⁴²¹-cortactin was localized at the leading edge and pY⁴⁶⁶-cortactin at a perinuclear area. In confluent cultures both pY⁴⁶⁶- and pY⁴²¹-cortactin isoforms were localized at the cell–cell contacts. In conclusion, in BCE cells, the most prominent appearance of cortactin was at the cell–cell contacts separate from the cortical actin ring. Isoform p80 was phosphorylated at Y⁴²¹ and associated with the Triton-insoluble fraction and isoform p85 was phosphorylated at Y⁴⁶⁶ and associated with the Triton-insoluble fraction.     

Why three Rho proteins? RhoA, RhoB, RhoC, and cell motility

Higher vertebrates have 3 Rho GTPases, RhoA, RhoB, and RhoC, which share 85% amino acid sequence identity. Here, we compare and contrast the roles of RhoA, B, and C in the regulation of the cytoskeleton and cell motility. Despite their similarity, some regulators and effectors show preferential interaction with RhoA, B, or C, and the three proteins show differences in function in cells. RhoA plays a key role in the regulation of actomyosin contractility. RhoB, which is localized primarily on endosomes, has been shown to regulate cytokine trafficking and cell survival, while RhoC may be more important in cell locomotion. In cancer cells, the expression and activity of RhoA, B, and C is altered in different ways. Together, this evidence suggests that although the 3 isoforms of Rho are structurally highly homologous, they have different cellular functions.     

Small heat shock proteins and the cytoskeleton: An essential interplay for cell integrity?

The cytoskeleton is a highly complex network of three major intracellular filaments, microfilaments (MFs), microtubules (MTs) and intermediate filaments (IFs). This network plays a key role in the control of cell shape, division, functions and interactions in animal organs and tissues. Dysregulation of the network can contribute to numerous human diseases. Although small HSPs (sHSPs) and in particular HSP27 (HSPB1) or αB-crystallin (HSPB5) display a wide range of cellular properties, they are mostly known for their ability to protect cells under stress conditions. Mutations in some sHSPs have been found to affect their ability to interact with cytoskeleton proteins, leading to IF aggregation phenotypes that mimick diseases related to disorders in IF proteins (i.e. desmin, vimentin and neuro-filaments). The aim of this review is to discuss new findings that point towards the possible involvement of IFs in the cytoprotective functions of sHSPs, both in physiological and pathological settings, including the likelihood that sHSPs such as HSPB1 may play a role during epithelial-to-mesenchymal transition (EMT) during fibrosis or cancer progression. This article is part of a Directed Issue entitled: Small HSPs in physiology and pathology.     

An optimized ultrasonication protocol for bacterial cell disruption and recovery of β-galactosidase fusion proteins

Summary In this work, we have developed and optimized an ultrasonication protocol for Escherichia coli recombinant cells, adapted to laboratory-scale release of -galactosidase fusion proteins. After a single sonication treatment of 15 minutes, about 30% of recombinant protein present in the sample remains still associated to cellular debris, and it can not be removed by increasing the sonication time. After a clarification step a second sonication treatment of the resuspended cell debris again releases only a 70% of the remaining product. Therefore, the application of two short, consecutive sonication treatments permits a global recovery yield of about 90%. The use of a new disruption buffer to stabilize -galactosidase allows the fusion proteins to maintain the active form throughout the process.     

Do the BEAF insulator proteins regulate genes involved in cell polarity and neoplastic growth?

It was reported that a chromosome with the BEAF^NP6377 (NP6377) allele leads to a loss of cell polarity and neoplastic growth in Drosophila melanogaster when homozygous ( Gurudatta et al., 2012). We had previously generated the BEAF^AB-KO (AB-KO) allele by homologous recombination and did not note these phenotypes ( Roy et al., 2007). Both alleles are null mutations. It was unclear why two null alleles of the same gene would give different phenotypes. To resolve this, we performed genetic tests to explore the possibility that the chromosome with the NP6377 allele contained other, second site mutations that might account for the different phenotypes. We found that the chromosome with NP6377 has at least two additional mutations. At least one of these, possibly in combination with the NP6377 allele, is presumably responsible for the reported effects on gene expression, cell polarity and neoplastic growth.     

DCD – a novel plant specific domain in proteins involved in development and programmed cell death

Background  

Recognition of microbial pathogens by plants triggers the hypersensitive reaction, a common form of programmed cell death in plants. These dying cells generate signals that activate the plant immune system and alarm the neighboring cells as well as the whole plant to activate defense responses to limit the spread of the pathogen. The molecular mechanisms behind the hypersensitive reaction are largely unknown except for the recognition process of pathogens. We delineate the NRP-gene in soybean, which is specifically induced during this programmed cell death and contains a novel protein domain, which is commonly found in different plant proteins.     

Production of membrane proteins using cell–free expression systems

Different overexpression systems are widely used in the laboratory to produce proteins in a reasonable amount for functional and structural studies. However, to optimize these systems without modifying the cellular functions of the living organism remains a challenging task. Cell-free expression systems have become a convenient method for the high-throughput expression of recombinant proteins, and great effort has been focused on generating high yields of proteins. Furthermore, these systems represent an attractive alternative for producing difficult-to-express proteins, such as membrane proteins. In this review, we highlight the recent improvements of these cell-free expression systems and their direct applications in the fields of membrane proteins production, protein therapy and modern proteomics.     

Fluorescent proteins in microbial biotechnology—new proteins and new applications

The recent advances over the past 5 years in the utilisation of fluorescent proteins in microbial biotechnology applications, including recombinant protein production, food processing, and environmental biotechnology, are reviewed. We highlight possible areas where fluorescent proteins currently used in other bioscience disciplines could be adapted for use in biotechnological applications and also outline novel uses for recently developed fluorescent proteins.     

Evolution of proteins formed by β-sheets: I. Plastocyanin and azurin

Plastocyanin and azurin form a family of small copper-containing proteins, active in the electron transport systems of plants and bacteria, respectively. The crystal structures of two members of this family have been determined: poplar leaf plastocyanin and Pseudomonas aeruginosa azurin. Both proteins contain two β-sheets, packed face-to-face. Using computed superpositions of the structures, we have aligned the sequences, identified homologous positions, and studied how the structures have changed as a result of mutations.The residues in the vicinity of the copper-binding site show minimal amino acid substitution and form almost identical structures. Other portions of these proteins are more variable in sequence and in structure. Buried residues tend to maintain their hydrophobic character, but mutations change their volume. The mean variation in volume of homologous buried residues is 54 ų. The differences in size and shape of these buried residues are accommodated by a 3.8 Å shift in relative position of the packed β-sheets. This shift does not affect the copper binding site, because the residues that form this site are in, or adjacent to, just one of the β-sheets.     

Aromatic side-chain interactions in proteins. Near- and far-sequence His–X pairs

Several studies have analysed aromatic interactions, involving mostly phenylalanine, tyrosine and tryptophan. Only a few studies have considered histidine as an interacting aromatic residue. An extensive analysis of aromatic His–X interactions is performed here on a data set of 593 PDB structures: 68% of the histidine are involved in aromatic pairs and 1271 non-redundant His–X pairs were analysed. Thirty percent of these pairs involve an aromatic partner less than 6 apart in the sequence. These near-sequence pairs correspond to conformations which stabilise secondary structures, mainly α-helices when the residues are 4 apart and β-strands when they are 2 apart in the sequence. The partners of the other His–X pairs (887, 70%) are more than 5 apart in the sequence. Of these far-sequence pairs, 35% bridge beta strands and only 9% helices. The near-sequence pairs are sterically constrained as supported by conformer distribution. The X partners of far-sequence His–X pairs are mainly “above” the histidine ring with tilted and normal rings, corresponding to a “T shape; face to edge” orientation. Phenylalanine, the only aromatic residue with no heteroatom, is a disfavoured partner, whereas histidine is the preferred one. Heteroatom–heteroatom interactions are favoured in near-sequence as well as in far-sequence His–His, His–Trp and His–Tyr pairs.     

Hydrogen peroxide. Ubiquitous in cell culture and in vivo?

Hydrogen peroxide (H2O2) is widely regarded as a cytotoxic agent whose levels must be minimized by the action of antioxidant defence enzymes. In fact, H2O2 is poorly reactive in the absence of transition metal ions. Exposure of certain human tissues to H2O2 may be greater than is commonly supposed; levels of H2O2 in the human body may be controlled not only by catabolism but also by excretion, and H2O2 could play a role in the regulation of renal function and as an antibacterial agent in the urine. Cell culture is a widely used method for the investigation of "physiological" processes such as signal transduction and regulation of gene expression, but chemical reactions involving cell culture media are rarely considered. Addition of reducing agents to commonly used cell-culture media can lead to generation of substantial amounts of H2O2. Some or all of the reported effects of ascorbic acid and polyphenolic compounds (e.g., quercetin, catechin, epigallocatechin, epigallocatechin gallate) on cells in culture may be due to H2O2 generation by interaction of these compounds with cell culture media.     

Biosynthesis of S-associated proteins following self- and cross-pollinations in Brassica campestris L. var. ‘T. 15’

Summary Homozygote plants for the (S) self-incompatibility gene have been produced in Brassica campestris L. var. T 15. Stigmas from plants designated S ₁ S ₁, S ₂ S ₂ and S ₄ S ₄ were extracted and their protein separated on an isoelectric focusing mini-gel. Differences were observed between proteins from stigmas of the three S-homozygous groups: S-genotype specific proteins were determined for S ₁ S ₁ and S ₂ S ₂ stigmas that were absent in the self-compatible S ₄ S ₄ stigmas. Carbon dioxide (CO₂), which is known to block the self-incompatibility reaction in Brassica, was applied to [³⁵S]-methionine unpollinated, self- and cross-pollinated stigmas to observe the effect of external CO₂ on the synthesis of these S-associated proteins. The results indicate that pollination triggers a dramatic reduction in protein synthesis in general and in the synthesis of S₂-associated protein after self-pollination in particular.     

M?ssbauer investigations of high-spin ferrous heme proteins. II. Chloroperoxidase, horseradish peroxidase, and hemoglobin.

Reduced samples of chloroperoxidase, horseradish peroxidase, and deoxyhemoglobin were studied by M?ssbauer spectroscopy in strong magnetic fields. The intricate paramagnetic spectra of chloroperoxidase were evaluated in detail in the framework of a spin Hamiltonian pertinent to high-spin ferrous iron. The studies strongly suggest that, in their reduced states, chloroperoxidase from Caldariomyces fumago and cytochrome P-450 from Pseudomonas putida have similar, if not identical ligand structures of the heme iron. The spectral similarities of these two proteins, noted in an earlier M?ssbauer investigation, are further explored and substantiated. Reduced horseradish peroxidase and deoxyhemoglobin, on the other hand, show high-field M?ssbauer spectra that differ considerably from each other and, in particular, from those of the P-450 type, suggesting a different ligand arrangement of the heme iron for each case.