Marcela Hermann

Hydrogen sulphide: A novel physiological inhibitor of LDL atherogenic modification by HOCl

Hypochlorite (HOCl), the product of the activated myeloperoxidase/H2O2/chloride (MPO/H2O2/Cl− ) system is favored as a trigger of LDL modifications, which may play a pivotal role in early atherogenesis. As HOCl has been shown to react with thiol-containing compounds like glutathione and N-acetylcysteine protecting LDL from HOCl modification, we have tested the ability of hydrogen sulfide (H2S)—which has recently been identified as an endogenous vasorelaxant—to counteract the action of HOCl on LDL. The results show that H2S could inhibit the atherogenic modification of LDL induced by HOCl, as measured by apolipoprotein alterations. Beside its HOCl scavenging potential, H2S was found to inhibit MPO (one may speculate that this occurs via H2S/heme interaction) and destroy H2O2. Thus, H2S may interfere with the reactants and reaction products of the activated MPO/H2O2/Cl− system. Our data add to the evidence of an anti-atherosclerotic action of this gasotransmitter taking the role of HOCl in the atherogenic modification of LDL into account.

The novel gaseous vasorelaxant hydrogen sulfide inhibits angiotensin-converting enzyme activity of endothelial cells

Objective Beside NO (nitric monoxide) and CO (carbon monoxide), H2S (hydrogen sulfide) has been identified recently as the third gasotransmitter. By acting directly on KATP-channels on smooth muscle cells (SMC) H2S possesses vasorelaxing properties. It has the potential to react with metal ions (i.e. Cu, Fe, Zn) in metalloproteins. Angiotensin-converting enzyme (ACE), responsible for vasoconstriction, is a zinc (Zn2+) containing enzyme. We therefore hypothesized that H2S may interact with the Zn2+ in the active center of ACE, modulating (inhibiting) enzyme activity. Methods ACE activity was measured on the surface of human endothelial cells (HUVECs) monolayers in culture, ex-vivo in umbilical veins and in HUVEC protein extracts. Quantitative real-time polymerase chain reaction (PCR) was used to study the effect of H2S on ACE mRNA expression in HUVECs. Results H2S inhibited the activity of ACE in HUVEC protein extracts in a dose-dependent manner, and only Zn2+ but not Cd2+, Ca2+ or Mg2+ could counteract the inhibitory effect. Cell-surface ACE activity was inhibited by H2S on HUVEC monolayers and in ex-vivo umbilical veins. No influence of H2S on ACE mRNA expression was observed. Conclusion H2S exhibits direct inhibitory action on ACE activity in HUVECs, obviously by interfering with the Zn2+ in the active center of the enzyme. Thus, beside the known influence of H2S on SMC KATP-channels, the observed direct ACE inhibitory effect may add to the vasorelaxant effect of H2S in the vasculature by reducing angiotensin II production and inhibiting bradykinin degradation.

Identification of reptilian genes encoding hair keratin-like proteins suggests a new scenario for the evolutionary origin of hair

The appearance of hair is one of the main evolutionary innovations in the amniote lineage leading to mammals. The main components of mammalian hair are cysteine-rich type I and type II keratins, also known as hard α-keratins or “hair keratins.” To determine the evolutionary history of these important structural proteins, we compared the genomic loci of the human hair keratin genes with the homologous loci of the chicken and of the green anole lizard Anolis carolinenis. The genome of the chicken contained one type II hair keratin-like gene, and the lizard genome contained two type I and four type II hair keratin-like genes. Orthology of the latter genes and mammalian hair keratins was supported by gene locus synteny, conserved exon–intron organization, and amino acid sequence similarity of the encoded proteins. The lizard hair keratin-like genes were expressed most strongly in the digits, indicating a role in claw formation. In addition, we identified a novel group of reptilian cysteine-rich type I keratins that lack homologues in mammals. Our data show that cysteine-rich α-keratins are not restricted to mammals and suggest that the evolution of mammalian hair involved the co-option of pre-existing structural proteins.

Identification of Novel Mammalian Caspases Reveals an Important Role of Gene Loss in Shaping the Human Caspase Repertoire

Proteases of the caspase family play central roles in apoptosis and inflammation. Recently, we have described a new gene encoding caspase-15 that has been inactivated independently in different mammalian lineages. To determine the dynamics of gene duplication and loss in the entire caspase gene family, we performed a comprehensive evolutionary analysis of mammalian caspases. By comparative genomics and reverse transcriptase-polymerase chain reaction analyses, we identified 3 novel mammalian caspase genes, which we tentatively named caspases-16 through -18. Caspase-16, which is most similar in sequence to caspase-14, has been conserved in marsupials and placental mammals, including humans. Caspase-17, which is most similar to caspase-3, has been conserved among fish, frog, chicken, lizard, and the platypus but is absent from marsupials and placental mammals. Caspase-18, which is most similar to caspase-8, has been conserved among chicken, platypus, and opossum but is absent from placental mammals. These gene distribution patterns suggest that, in the evolutionary lineage leading to humans, caspase-17 was lost after the split of protherian and therian mammals and caspase-18 was lost after the split of marsupials and placental mammals. In the canine genome, the number of caspases has been reduced by the fusion of the neighboring genes caspases-1 and -4, resulting in a single coding region. Further lineage-specific gene inactivations were found for caspase-10 in murine rodents and caspase-12 in humans, rabbit, and cow. Lineage-specific gene duplications were found for caspases-1, -3, and -12 in opossum and caspase-4 in primates. Other caspases were generally conserved in all mammalian species investigated. Using the positions of introns as stable characters during recent vertebrate evolution, we define 3 phylogenetic clades of caspase genes: caspases-1/-2/-4/-5/-9/-12/-14/-15/-16 (clade I), caspases-3/-6/-7/-17 (clade II), and caspases-8/-10/-18/CFLAR (clade III). We conclude that gene inactivations have occurred in each of the 3 caspase clades and that gene loss has been as critical as gene duplication in the evolution of the human repertoire of caspases.

Hydrogen sulfide destroys lipid hydroperoxides in oxidized LDL.

LOOHs (lipid hydroperoxides) in oxLDL [oxidized LDL (low-density lipoprotein)] are potentially atherogenic compounds. Recently, H2S was identified as the third endogenous gasotransmitter in the vasculature. H2O2 is known to be destroyed by H2S. Assuming that H2S may also react with LOOHs, the results show that H2S can destroy LOOHs in oxLDL. The ability of LOOH-enriched LDL to induce HO-1 (haem oxygenase 1) in endothelial cells was abolished by H2S pretreatment. HPLC analysis showed that 9-HPODE [(9S)-hydroperoxy-(10E,12Z)-octadecadienoic acid], a compound found in oxLDL, was reduced to 9-HODE [(9S)-hydroxy-(10E,12Z)-octadecadienoic acid] in the presence of H2S. Thus H2S may act as an antiatherogenic agent by reducing LOOHs to the less reactive LOHs and could abrogate the pathobiological activity of oxLDL.

Evolutionary Origin and Diversification of Epidermal Barrier Proteins in Amniotes

The evolution of amniotes has involved major molecular innovations in the epidermis. In particular, distinct structural proteins that undergo covalent cross-linking during cornification of keratinocytes facilitate the formation of mechanically resilient superficial cell layers and help to limit water loss to the environment. Special modes of cornification generate amniote-specific skin appendages such as claws, feathers, and hair. In mammals, many protein substrates of cornification are encoded by a cluster of genes, termed the epidermal differentiation complex (EDC). To provide a basis for hypotheses about the evolution of cornification proteins, we screened for homologs of the EDC in non-mammalian vertebrates. By comparative genomics, de novo gene prediction and gene expression analyses, we show that, in contrast to fish and amphibians, the chicken and the green anole lizard have EDC homologs comprising genes that are specifically expressed in the epidermis and in skin appendages. Our data suggest that an important component of the cornified protein envelope of mammalian keratinocytes, that is, loricrin, has originated in a common ancestor of modern amniotes, perhaps during the acquisition of a fully terrestrial lifestyle. Moreover, we provide evidence that the sauropsid-specific beta-keratins have evolved as a subclass of EDC genes. Based on the comprehensive characterization of the arrangement, exon–intron structures and conserved sequence elements of EDC genes, we propose new scenarios for the evolutionary origin of epidermal barrier proteins via fusion of neighboring S100A and peptidoglycan recognition protein genes, subsequent loss of exons and highly divergent sequence evolution.

The patatin-like lipase family in Gallus gallus.

BackgroundIn oviparous species, genes encoding proteins with functions in lipid remodeling, such as specialized lipases, may have evolved to facilitate the assembly and utilization of yolk lipids by the embryo. The mammalian gene family of patatin-like phospholipases (PNPLAs) has received significant attention, but studies in other vertebrates are lacking; thus, we have begun investigations of PNPLA genes in the chicken (Gallus gallus).ResultsWe scanned the draft chicken genome using human PNPLA sequences, and performed PCR to amplify and sequence orthologous cDNAs. Full-length cDNA sequences of galline PNPLA2/ATGL, PNPLA4, -7, -8, -9, and the activator protein CGI-58, as well as partial cDNA sequences of avian PNPLA1, -3, and -6 were obtained. The high degree of sequence identities (~50 to 80%) between the avian and human orthologs suggests conservation of important enzymatic functions. Quantitation by qPCR of the transcript levels of PNPLA s and CGI-58 in 21 tissues indicates that expression patterns and levels diverge greatly between species. A particularly interesting tissue in which certain PNPLAs may contribute to physiological specialization is the extraembryonic yolk sac.ConclusionKnowledge about the exact in-vivo functions of PNPLAs in any system is still sparse. Thus, studies about the temporal expression patterns and functions of the enzymes identified here, and of other already known extracellular lipases and co-factors, in the yolk sac and embryonic tissues during embryogenesis are called for. Based on the information obtained, further studies are anticipated to provide important insights of the roles of PNPLAs in the yolk sac and embryo development.

Trichohyalin-Like Proteins Have Evolutionarily Conserved Roles in the Morphogenesis of Skin Appendages

S100 fused-type proteins (SFTPs) such as filaggrin, trichohyalin, and cornulin are differentially expressed in cornifying keratinocytes of the epidermis and various skin appendages. To determine evolutionarily conserved, and thus presumably important, features of SFTPs, we characterized nonmammalian SFTPs and compared their amino acid sequences and expression patterns with those of mammalian SFTPs. We identified an ortholog of cornulin and a previously unknown SFTP, termed scaffoldin, in reptiles and birds, whereas filaggrin was confined to mammals. In contrast to mammalian SFTPs, both cornulin and scaffoldin of the chicken are expressed in the embryonic periderm. However, scaffoldin resembles mammalian trichohyalin with regard to its expression in the filiform papillae of the tongue and in the epithelium underneath the forming tips of the claws. Furthermore, scaffoldin is expressed in the epithelial sheath around growing feathers, reminiscent of trichohyalin expression in the inner root sheath of hair. The results of this study show that SFTP-positive epithelia function as scaffolds for the growth of diverse skin appendages such as claws, nails, hair, and feathers, indicating a common evolutionary origin.

Essential role of the keratinocyte-specific endonuclease DNase1L2 in the removal of nuclear DNA from hair and nails

Degradation of nuclear DNA is a hallmark of programmed cell death. Epidermal keratinocytes die in the course of cornification to function as the dead building blocks of the cornified layer of the epidermis, nails, and hair. Here, we investigated the mechanism and physiological function of DNA degradation during cornification in vivo. Targeted deletion of the keratinocyte-specific endonuclease DNase1-like 2 (DNase1L2) in the mouse resulted in the aberrant retention of DNA in hair and nails, as well as in epithelia of the tongue and the esophagus. In contrast to our previous studies in human keratinocytes, ablation of DNase1L2 did not compromise the cornified layer of the epidermis. Quantitative PCRs showed that the amount of nuclear DNA was dramatically increased in both hair and nails, and that mitochondrial DNA was increased in the nails of DNase1L2-deficient mice. The presence of nuclear DNA disturbed the normal arrangement of structural proteins in hair corneocytes and caused a significant decrease in the resistance of hair to mechanical stress. These data identify DNase1L2 as an essential and specific regulator of programmed cell death in skin appendages, and demonstrate that the breakdown of nuclear DNA is crucial for establishing the full mechanical stability of hair.

Convergent evolution of cysteine-rich proteins in feathers and hair

BackgroundFeathers and hair consist of cornified epidermal keratinocytes in which proteins are crosslinked via disulfide bonds between cysteine residues of structural proteins to establish mechanical resilience. Cysteine-rich keratin-associated proteins (KRTAPs) are important components of hair whereas the molecular components of feathers have remained incompletely known. Recently, we have identified a chicken gene, named epidermal differentiation cysteine-rich protein (EDCRP), that encodes a protein with a cysteine content of 36%. Here we have investigated the putative role of EDCRP in the molecular architecture and evolution of feathers.ResultsComparative genomics showed that the presence of an EDCRP gene and the high cysteine content of the encoded proteins are conserved among birds. Avian EDCRPs contain a species-specific number of sequence repeats with the consensus sequence CCDPCQ(K/Q)(S/P)V, thus resembling mammalian cysteine-rich KRTAPs which also contain sequence repeats of similar sequence. However, differences in gene loci and exon-intron structures suggest that EDCRP and KRTAPs have not evolved from a common gene ancestor but represent the products of convergent sequence evolution. mRNA in situ hybridization demonstrated that chicken EDCRP is expressed in the subperiderm layer of the embryonic epidermis and in the barbule cells of growing feathers. This expression pattern supports the hypothesis that feathers are evolutionarily derived from the subperiderm.ConclusionsThe results of this study suggest that convergent sequence evolution of avian EDCRP and mammalian KRTAPs has contributed to independent evolution of feathers and hair, respectively.