Carlo Ivan Mitolo

The HIV-1 Rev binding family of proteins: the dog proteins as a study model.

Various proteins that are required for the building of new complete human immunodeficiency type 1 virions (HIV-1) are coded by unspliced or partly spliced virus-derived mRNAs. HIV-1 has developed special strategies for moving these mRNAs to the cytoplasm to be translated. In the nucleus of the infected cell the virus-derived protein Regulator of expression of viral proteins (Rev) can bind both the viral intron-containing mRNAs and the cellular co-factor HIV-1 Rev binding protein (HRB) and this complex may be shuttled through the nuclear pores. HRB genes have been relatively well conserved during evolution, from Drosophila to humans. However, as a consequence of reading-frame shifts due to nt insertions/deletions, the protein products generated may differ considerably from the prototypal HRB protein, which comprises one Arf-GAP zinc finger domain, several Phenylalanine-Glycine (FG) motifs and four Asparagine-Proline-Phenylalanine (NPF) motifs. This variability is best exemplified by four HRB proteins of the dog, which are discussed here in more detail. The hypothesis is advanced that atypical HRB proteins may not be able to bind Rev and possibly have other, still undetermined, functions. Since the cellular co-factor HRB is essential for viral replication and spread but is not required for cell viability and main bodily functions, it might be an attractive candidate for anti-HIV-1 drug targeting.

CD14 major role during lipopolysaccharide-induced inflammation in chick embryo cardiomyocytes.

CD14 is a surface differentiation antigen that functions as a receptor for bacterial lipopolysaccharide. The cellular signaling events that lead to lipopolysaccharide-induced production of inflammatory mediators are the primary cause of myocardial dysfunction observed in sepsis. Here, we evaluated the role of CD14 in chick embryo cardiomyocytes stimulated with lipopolysaccharide. CD14 expression was detected by confocal laser microscopy observation and by immunoblotting analysis. Moreover, we provided evidence for CD14-dependent functional responses of lipopolysaccharide-stimulated cardiomyocytes in terms of tumor necrosis factor (TNF)-alpha and nitric oxide (NO) production. Attenuated TNF-alpha and NO secretion, following anti-CD14 treatment of cardiomyocytes, suggested a role for this receptor in lipopolysaccharide-mediated cell responses. We also evidenced that labeled lipopolysaccharide was internalized and localized next to the Golgi complex, at the level of lysosomes, and in the perinuclear zone. The intracytoplasmatic transport seems to depend on the contractile apparatus, because cell pretreatment with cytochalasin D prevented lipopolysaccharide internalization and reduced both TNF-alpha and NO release. Lipopolysaccharide internalization was dependent on CD14 receptor, since anti-CD14 pre-treatment prevented endotoxin uptake by cardiomyocytes. Results demonstrated: (1) CD14 is expressed on the surface membrane of cardiomyocytes; (2) CD14 is involved in cytoskeletal dependent lipopolysaccharide internalization at specific cytoplasmatic locations; (3) CD14 plays a role in lipopolysaccharide-mediated responses by cardiomyocytes after lipopolysaccharide internalization.

Viral sequence integration into introns of chemokine receptor genes.

Viral DNA sequences are able to integrate into the non-coding DNA sections of the genome of human cells which have been infected, either spontaneously or experimentally. We have made a data-base search for integration events of non-endogenous viruses into the introns of chemokine receptor sequences. A BLAST search of all viral DNA sequences, using the intronic sequences as “Query,” returned several significant alignments. However, due to the high reiteration rate of the non-coding sequences in the human genome, it became necessary to re-examine the individual alignments to verify whether the virus-flanking intronic sequence was really located in a chemokine receptor intron. We found only one unquestionable event of viral insertion of a section of a long terminal repeat of the murine leukemia virus within the first intron of the CC chemokine receptor 7 gene. Possible biological effects of such an insertion are discussed. Further experimental or clinical research could demonstrate the occurrence of other intronic viral insertions in human chemokine receptor genes.

Formyl Peptide Receptors on Immune and Nonimmune Cells: Analysis of Sequence Conservation in FPR Genes

Formyl peptides are oligopeptides released by Gram-negative bacteria. So far, specific formyl peptide receptors (FPRs) have been described in mammals only. FPRs are seven-transmembrane G-coupled molecules and make up a relatively homogeneous group, although exhibiting different levels of affinity for the ligands. We examined the patterns of conservation/mutation within the FPR group of genes, as studied in 16 mRNAs from different species. Following alignment of the coding sections, those nucleotides identical in at least 15 sequences were assigned a “conservation index” 2; those with 8–14 identities an index 1; those with less than 8 identities an index zero. The cumulative average conservation index was 1.36. The autocorrelation function and the power spectrum of the whole series of indexes demonstrated a 3-unit periodicity. This periodicity is explained by the fact that the average conservation indexes of the first, second and third nucleotides of the coding triplets were 1.46, 1.55 (both above the mean), and 1.06 (below the mean), respectively, so that correlations at lag 3 tend to be all positive. In mRNAs, regardless of the position in the coding triplets, T is significantly more frequently conserved (average index = 1.60) than A, C, and G (1.21 – 1.38). In the nucleotides with conservation index 1 or zero, we recorded the two more frequently represented bases. In 35% of mRNA nucleotides the two more frequently represented bases were C and T; in 28% of cases the two more frequently represented bases were A and G; other couples occurred with lower frequencies. Both mutations may arise following C methylation with subsequent transformation into T (by deamination), either in the template or the coding DNA strand. Thus, we hypothesized that in FPR mRNAs there is an evolutionary trend of transformation from G to A and from C to T, the latter being the more stable of the bases.

Evidence for endogenous retroviruses in human chemokine receptor gene introns: possible evolutionary inferences and biological roles.

The human chemokine receptor (CKR) genes CCR2, CCR6, CCR7, CCR9, CCR10, CXCR4, and CXCR5 harbor one or two introns. CCR7, CCR9, CCR10, and CXCR5 introns, (but not CCR2, CCR6, and CXCR4 introns) encompass retrovirus-like inserts with the characteristics of SINEs (short interspersed nuclear elements) up to 300 nucleotides (nt) long. Other characteristic elements of the retroviral genome, such as long terminal repeats and gag, pol, and env genes, are lacking. The inserts likely derived from one (or more) of the following retroviruses: XA34 (NCBI GenBank Nucleotides, U29659), HERV-P-T47D (AF087913), ERV FTD (U27241), HERV-K (Y17832), HML6p (U86698), HERV-H/env60 (AJ289710), XA38 (U37066). Virus-like inserts are remarkably homogeneous in all CKR introns, with nt identities of about 80%. Percentages of nt identities between the CKR inserts and the corresponding viral sequences are also about 80%. With reference to the CKR sequence, the viral sequence aligns in some instances Plus/Plus (XA34, HML6p, HERV-H/env60, and XA38) and in other instances Plus/Minus (HERV-P-T47D, ERV FTD, and HERV-K). Some aspects of the evolution of retroviruses and CKRs as well as hypotheses on the biological significance of the SINE inserts are discussed.

An analysis of the human and mouse CXCR5 gene introns

Both mouse and human chemokine receptor CXC motif 5 (CXCR5) genes exhibit one single intron interrupting the coding sequence. The mouse intron is 12053 nucleotides (nt) long; the human intron is 9603 nt long. Sections of the mouse intron significantly align plus/plus with sections of the human intron; the aligned segments are in the same order in mouse as in man and overall cover 13% of the mouse sequence and 17% of the human sequence. The human CXCR5 intron harbors sequences derived from retroviruses (human endogenous retroviruses). The mouse intron comprises very similar sequences. About 70% of the mouse intron sequence is ‘specific’ to this gene, while sequences in the rest of the intron are shared with many other genes located on different chromosomes. In the human the coverage by specific sequences is about 87%. Thus, the contribution of transposable elements is significantly higher in mouse (30%) than in man (13%). Intra-intronic plus/minus alignments exist in mouse (10 couples) and man (two couples): these may form stem and loop structures determining the secondary structure of the corresponding pre-mRNAs.

Mutation Patterns in the Chemokine CXC Receptor 4 Gene Subfamily

Six representative CXCR4 mRNAs of fish, amphibia, birds, and mammals were selected to study the pattern of conservation/mutation of the individual nt of the coding sequences. According to an arbitrary conservation index ranging from 1 to 6, the indexes of conservation were: 5.04 for the first nt of coding triplets; 5.34 for the second nt of triplets, and 3.75 for the third nt of triplets. The average conservation index of the individual triplets was 4.71. The conservation index of the seven hydrophobic transmembrane domains was 5.60, while the cumulative conservation index of the intracytoplasmic and extracellular domains was 4.63. Separate autocorrelation and power spectral analyses of the series of conservation indexes for the first nt, the second nt and the triplets demonstrated a modest “basic” positive correlation for about the first 20 lags and accordingly some power concentration at the lower frequencies (long periods). Within the triplets, the correlation was studied between the conservation indexes of nt 1 and 2, 1 and 3, and 2 and 3. Correlations of 1 with 3 and 2 with 3 were positive, but in the range of the basic local correlation, whereas the correlation between the first and second nt was significantly higher. This correlation, together with the higher conservation of the second nt as compared to the first (two patterns also found in the formyl peptide receptors), are likely to have been established by selection processes directed towards a functional conservation or a “functional repair.”

Mutation, selection, and functional repair in formyl peptide receptor genes: a view on the selection processes occurring in this gene subfamily.

Formyl peptides (FPs) released by some bacteria are powerful chemoattractants and activators of granulocytes, monocytes, and macrophages, acting through the members of a subfamily of specific seven-transmembrane G-protein–coupled formyl peptide receptors (FPRs), which are expressed only in mammals. Upon stimulation, granulocytes chemotactically move towards sites of maximal FP concentration, and release different bactericidal lytic enzymes and reactive oxygen species (ROI). In some instances, such as ischemia/reperfusion, the proinflammatory mediators released by the injured tissues and the intestinal bacteria and endotoxins, which may permeate across the damaged mucosal barrier, prime the inflowing granulocytes for an enhanced ROI production, resulting in severe damage to the host tissues. In this investigation 16 representative FPR and FPR-like mRNAs were selected to study the pattern of mutation/conservation of the individual nucleotides (nt) in the coding sequences. Mutations occur in 56.7%, 46.4%, and 87.5 % of cases in the first, second, and third nt, respectively, of the coding triplets. A probabilistic analysis demonstrated a significant nonrandom linkage between mutations in the first and second nt. Furthermore, the triplets that are variously double-mutated in the first two nt code, on average, for more hydrophobic amino acids (AA) in the transmembrane segments and more hydrophilic AA in the external and intracytoplasmic segments, thus preserving the general structure of the receptor. The authors hypothesize that when in one of the first two nt a mutation leading to a nonfunctioning protein product occurred, the mutated gene was eventually eliminated; however, a second mutation occurring in the other previously unmutated nt may have led to a protein product that is compatible with functional activity, although mutated in one (noncritical) AA. Such double mutations effecting a “functional repair” have thus survived and are retained among the extant sequences. Moreover, the combined mutation of all three nt in coding triplets occurs with a significantly higher than random frequency and this finding may be interpreted in a similar way.

Modeling of granulocyte cytoskeletal responses following fMLP challenging.

Formyl peptides released from Gram-negative bacteria ligate a group of specific mammalian receptors, expressed mainly on granulocytes, monocytes, and macrophages. Receptor ligation activates different transduction cascades, eventually leading to the release of reactive oxygen species and other bactericidal chemical species, and the activation of the actin cytoskeleton with extension of lamellipodia and migration toward the sites of maximal formyl peptide concentration. In vitro, under conditions of nongradient formyl peptide concentrations, lamellipodia form all around the cell contour (chemokinesis). In granulocytes challenged under these conditions with N-formyl-methionyl-leucyl-phenylalanine, (i) the power spectrum of the contour of activated cells shows a peak at a specific periodicity, indicating that the lamellipodial extension is not completely random but stochastically conforms to a deterministic scheme, and (ii) the morphological response (percent of cells exhibiting chemokinesis) tends to reach a maximum at certain drug concentrations, then declining at higher concentrations. Accordingly, the logarithm of the drug concentration-polarizing effect curve is bell-shaped. Herein we illustrate theoretical models for the simulation of these two components of the chemokinetic responses. We show that the main traits of the general morphology and arrangement of lamellipodia may be simulated by an algorithm that starting from a situation of random distribution of active receptors on the cell membrane, encompasses in the successive calculation cycles both a local autocatalytic enhancement of the actin polymerization and a relative inhibition of the actin polymerization at some distance from the more active polymerization foci. In addition, a drug log concentration-polarizing effect bell-shaped curve may be simulated by assuming that the N-formyl-methionyl-leucyl-phenylalanine, while binding with high affinity to the specific receptor, is also able to bind to another lower affinity receptor that may effect depolarizing actions or, more generally, metabolic blocking effects. Under these conditions, at low drug concentrations the polarizing effect brought about by the ligation of the specific receptor is largely predominant. However, as the drug concentration increases and the specific receptors approach saturation, the inhibitory effects become more and more powerful and the net polarizing effect is reduced.

Differential Conservation of Nucleotides and Conservation/Mutation Correlations Between Nucleotides, with Special Reference to CXC 1 and 4 and FP Receptors Involved in Immune Regulation

Random mutations of the first nucleotide of a coding triplet alter the hydropathic character of 27 % of the hydrophobic amino acids and of 23 % of the hydrophilic amino acids, while random mutations of the second nucleotide alter the hydropathic character of 82 % of the hydrophobic amino acids and of 47 % of the hydrophilic amino acids. In cases of a change of the hydropathic character, a second random mutation in the previously unmutated first or second nucleotide causes reversion to the original character of an additional 11 % of the originally hydrophobic-coding triplets and an additional 14 % of the originally hydrophilic-coding triplets (on average). Thus, a selection oriented towards the preservation of the hydropathic character of amino acids may be expected to eventually result in a higher conservation of the second nucleotide (as compared to the first). In the case of uncorrected mutations of one of the two first nucleotides, it may be expected that appropriate second mutations in the other unaffected nucleotide will be positively selected. This would result in a positive correlation between the conservation/mutation indexes of the two first nucleotides, as these would be prevailingly either both conserved or both mutated. We examined six groups of coding mRNA sequences: chemokine CXC 1 and 4 and formyl peptide receptors; a group comprising different receptors of the rhodopsin-like superfamily, together with some viral sequences which share significant homologies with these receptors; a group of viral sequences with homologies with the rhodopsin-like receptors; a group of solute carriers. In all the experimental groups the second nucleotide of the triplet was the most conserved and a significant positive correlation existed between conservation/mutation indexes of the two first nucleotides. Similar conservation/mutation patterns could be of more general occurrence in the genome, as a consequence of selection processes.