Burn Injury Reduces Neutrophil Directional Migration Speed in Microfluidic Devices

Thermal injury triggers a fulminant inflammatory cascade that heralds shock, end-organ failure, and ultimately sepsis and death. Emerging evidence points to a critical role for the innate immune system, and several studies had documented concurrent impairment in neutrophil chemotaxis with these post-burn inflammatory changes. While a few studies suggest that a link between neutrophil motility and patient mortality might exist, so far, cumbersome assays have prohibited exploration of the prognostic and diagnostic significance of chemotaxis after burn injury. To address this need, we developed a microfluidic device that is simple to operate and allows for precise and robust measurements of chemotaxis speed and persistence characteristics at single-cell resolution. Using this assay, we established a reference set of migration speed values for neutrophils from healthy subjects. Comparisons with samples from burn patients revealed impaired directional migration speed starting as early as 24 hours after burn injury, reaching a minimum at 72–120 hours, correlated to the size of the burn injury and potentially serving as an early indicator for concurrent infections. Further characterization of neutrophil chemotaxis using this new assay may have important diagnostic implications not only for burn patients but also for patients afflicted by other diseases that compromise neutrophil functions.     

Sublocalization of an Ataxia-Telangiectasia Gene Distal to D11S384 by Ancestral Haplotyping In Costa Rican Families

In an effort to localize a gene for ataxia-telangiectasia (A-T), we have genotyped 27 affected Costa Rican families, with 13 markers, in the chromosome 11q22-23 region. Significant linkage disequilibrium was detected for 9/13 markers between D11S1816 and D11S1391. Recombination events observed in these pedigrees places A-T between D11S1819 and D11S1960. One ancestral haplotype is common to 24/54 affected chromosomes and roughly two-thirds of the families. Inferred (ancestral) recombination events involving this common haplotype in earlier generations suggest that A-T is distal to D11S384 and proximal to D11S1960. Several other common haplotypes were identified, consistent with multiple mutations in a single gene. When considered together with all other evidence, this study further sublocalizes the major A-T locus to ≈200 kb, between markers S384 and S535.     

Physical mapping of an adult plant stripe rust resistance gene from Triticum monococcum

Stripe rust (Puccinia striiformis f. sp. tritici) is one of the major devastating disease which causes large reduction in wheat yield. T. monococcum is an attractive diploid species for gene discovery in wheat with smaller genome size of 5700 Mb compared to 17,300 Mb of bread wheat. An adult plant stripe rust resistance QTL QYrtm.pau-2A was mapped on chromosome 2A flanked by two SSR markers Xwmc170 and Xwmc407. In the present study, two gene based markers Pau_Ta2AL_Gene45 and Pau_Ta2AL_Gene54 developed from 2A specific ESTs were found to map close to QYrtmpau-2A to narrow down the region for candidate gene identification. Utilizing sequence information of these two markers, four BAC clones were identified from the Minimum Tiling Path of 2AL assembly and were sequenced. SSR markers were designed from these BAC sequences and mapped to chromosome 2A. A 50 Mb region of wheat chromomse 2A was identified to harbor stripe rust resistance gene of T. monococcum. Gene based markers identified in the present investigation can be used for marker assisted introgression of QYrtm.pau-2A from T. monococcum to cultivated wheat.     

Meta-analysis of Genetic Structure and Association of Prolactin Gene with Performance Traits in Dairy Cattle in India

The present meta-analysis was carried to provide the more reliable estimates of gene frequency and association of Rsa 1 generated candidate genotype of prolactin gene within exon-3 with performance traits in 1198 Indian dairy cows using data from 15 published studies. Six genetic models viz., codominant (AA vs. AB, AA vs. BB and AB vs. BB), dominant (AA+AB vs. BB), completely over dominant (AA+BB vs. AB) and recessive (AA vs. AB+BB) were used to obtain standardized mean difference (SMD) between genotypes. Meta-analysis showed that the gene frequency of A allele (156 bp) was 0.60 (95% confidence interval (CI) 0.54, 0.65). In association analysis, cows with AB genotype [SMD?=?0.65, 95% CI 0.00, 1.30] had significantly (P?<?0.05) higher lactation milk yield (LMY) as compared to BB genotype, whereas AA and AB genotypes had similar trend. Likewise, AA?+?AB also had larger effect [SMD?=?2.31, 95% CI 0.21, 4.10] on LMY as compared to BB. Cows with AB genotype had significantly lower age at first calving (AFC) with small effect [SMD (AA vs. AB)?=?1.38, 95% CI 0.06, 2.70] and medium effect [SMD (AB vs. BB)?=????3.83, 95% CI???6.41,???1.24] as compared to cows with AA and BB genotypes, respectively. This finding was confirmed under dominant and completely over dominant models. In case of fat%, AA genotype showed negative effect (SMD?=????0.51, 95% CI???0.84,???0.17) under recessive model. It was concluded that the propagation of allele A is promising to help dairy farmers to improve the genetic quality of their dairy cows.

     

N-terminal Protein Processing: A Comparative Proteogenomic Analysis

N-terminal methionine excision (NME) and N-terminal acetylation (NTA) are two of the most common protein post-translational modifications. NME is a universally conserved activity and a highly specific mechanism across all life forms. NTA is very common in eukaryotes but occurs rarely in prokaryotes. By analyzing data sets from yeast, mammals and bacteria (including 112 million spectra from 57 bacterial species), the largest comparative proteogenomics study to date, it is shown that previous assumptions/perceptions about the specificity and purposes of NME are not entirely correct. Although NME, through the universal enzymatic specificity of the methionine aminopeptidases, results in the removal of the initiator Met in proteins when the second residue is Gly, Ala, Ser, Cys, Thr, Pro, or Val, the comparative genomic analyses suggest that this specificity may vary modestly in some organisms. In addition, the functional role of NME may be primarily to expose Ala and Ser rather than all seven of these residues. Although any of this group provide “stabilizing” N termini in the N-end rule, and de facto leave the remaining 13 amino acid types that are classed as “destabilizing” (in higher eukaryotes) protected by the initiator Met, the conservation of NME-substrate proteins through evolution suggests that the other five are not crucially important for proteins with these residues in the second position. They are apparently merely inconsequential players (their function is not affected by NME) that become exposed because their side chains are smaller or comparable to those of Ala and Ser. The importance of exposing mainly two amino acids at the N terminus, i.e. Ala and Ser, is unclear but may be related to NTA or other post-translational modifications. In this regard, these analyses also reveal that NTA is more prevalent in some prokaryotes than previously appreciated.Although methionine is used to initiate protein synthesis for essentially all proteins, it is subsequently removed in a large percentage of cases, either by cleavage of an N-terminal “signal ” peptide (as part of cellular translocation mechanisms or precursor activations) or by the action of specific methionine aminopeptidases (MetAPs). Approximately two-thirds of the proteins in any proteome are potential substrates for the latter N-terminal methionine excision (NME),¹ and MetAPs appear in all organisms from bacteria to eukaryotes (1). The second, or P2, amino acid in protein substrates is crucially important for NME because MetAP specificity mainly depends on the nature of this residue, a selectivity that is conserved across all species (1–5). These enzymes generally excise the N-terminal Met when the second residue is Gly, Ala, Ser, Thr, Cys, Pro, or Val (3, 6, 7), which are the amino acids smallest in size (based on radius of gyration of the side chain (8)). NME is a necessary process for proper cell functioning; it is included in the minimal genome set of eubacteria (9). Eukaryotes contain two MetAPs derived from a version in bacteria (MetAP1), and another found in archea (MetAP2) (11). Just as the deletion of MetAP eubacteria is lethal, the deletion of both MetAPs in yeast is also lethal (10).In 1988, Arfin and Bradshaw (2) observed that the specificity of NME coincided with that of the N-end rule (NER) (12, 13), a ubiquitin-dependent protein degradation process that is based on the recognition of N-terminal residues. The stabilizing residues for the NER include Gly, Ala, Ser, Cys, Thr, Pro, and Val and, with the exception of Met, the destabilizing residues are all found to be in the class of P2-residues that are not substrates for the MetAPs. This suggested that NME acts to release Met from proteins whose stability is unaffected by the NER creating at the same time a second class of proteins, who have the potential for regulated turnover downstream of the cotranslational processing, when, and if, the N-terminal Met is subsequently removed by a mechanism other than the cotranslational action of the MetAPs. However, despite extensive studies, this type of programmed protein turnover (requiring downstream removal of Met) has not been demonstrated to occur. An implication of this correlation is that exposing of the stabilizing residues may also contribute to increasing their lifetime.The stabilizing residues exposed by the action of the MetAPs can be further modified. The most extensive of these reactions is N-terminal acetylation (NTA), which can occur on as much as 70–80% of the mass of the soluble protein in eukaryotes. Although the specificity of the N-acetyltransferase (NAT) responsible is not as rigid as the MetAPs, the principal substrates in the stabilizing class are usually the four smallest residues (Gly, Ala, Ser, and Thr) (6, 14). A second class of NATs can also modify the retained Met when the adjacent residues are Asp, Glu or Asn (15). The functional importance of this modification (in either case) is not known although it has been suggested that it may exert a protective effect against spurious aminopeptidase cleavages. Recently, Hwang et al. (16) have extended the NER to include Nα-acetylated termini as also destabilizing thus providing another possible function for this modification. In contrast, to date, very few instances of Nα-acetylation have been observed in bacteria. Other modifications can also occur in both eukaryotes and prokaryotes although they are generally much more limited in scope.The specificity of the MetAPs suggest an apparent connection between NME and protein degradation. However, this connection has never been examined using high-throughput mass spectrometric data or a comparative genomics approach; thus it remains unclear whether exposing these stabilizing residues contributes to increasing protein half-life and thus represents a primary purpose of NME. (The connection between NME and NER in bacteria, which has an NER with a somewhat different profile (17), is even more obscure.) Recent studies provide some examples where disruption of NME via a single-residue substitution in the P2 position causes protein degradation (18–20); however, some of these experimental results are in conflict with the NER (13). Giglione et al. (20) have shown that NME triggers degradation of D2 protein in Caenorhabditis reinhardtii in the PSII complex after replacing the second (stabilizing) Thr residue by another amino acid to prevent NME. This replacement results in early degradation of D2 and instability of the PSII complex. From this, Giglione et al. (20) postulated that NME determines protein life-span via currently unknown machinery. However, because Bachmair et al. (12) classified Met as a stabilizing residue, it is not entirely clear why substituting one stabilizing residue (Met) by another one (Gly, Ala, Ser, Cys, Thr, Pro, or Val) should affect protein stability and the substitution may have other deleterious effects that are manifested in different ways.The logic for analyzing NME and NER is shown in Fig. 1. NME exposes 7 different residues as new N termini of proteins. The natural conclusion that has become a dogma of NME is that these seven residues are exposed for a functional reason. The broad scope of NME suggests a universal reason that surpasses any particular protein''s role. In turn the comparative genomics postulate (function suggests conservation) leads to the conclusion that the seven residues should be evolutionarily conserved at position P2 of proteins. However, because only two out of the seven residues are conserved, we argue that one of the two assumptions in Fig. 1A must be incorrect and put forth the alternative logic depicted in Fig. 1B, which matches our analysis across dozens of species. According to this logic, NME accomplishes the goal of exposing Ala and Ser by exposing all residues with side chains smaller or comparable in size to Ala and Ser (G, T, V, P, and C). These residues are thus inconsequential players that are not functionally important (and are not evolutionarily conserved) at P2.Open in a separate windowFig. 1.Two alternative cases for NME function. A, NME exposes seven residues to be new N termini of proteins. Because this is presumably for some functional reason, the conventional assumption is that all seven residues must have functional importance as N termini. By the comparative genomics postulate (as defined in the text), evolutionary conservation of all seven at P2 should be observed. If all of these residues are not conserved, one of the two assumptions must be incorrect; either not all seven residues are important or the comparative genomics postulate is invalid. B, Given that the comparative genomics postulate holds, and only two of the seven residues are of functional importance as N termini, then the other five residues are inconsequential players and only these two residues should be evolutionarily conserved.In this report, we examine the connection between the specificity of NME and stabilizing residues of NER. In doing so, data sets from bacteria (including 112 million mass spectrometric spectra from 57 species), yeast, and mammals, were analyzed for N-terminal peptides both with respect to the excision (or not) of initiator Met residues and the distribution of P2-residues. The results reveal a strong preference of Ala and Ser as P2-residues. However, this process does not appear to be linked to the NER other than being generally compatible with it. These studies also demonstrate a much greater than expected number of Nα-acetylation events in some bacteria.