Genome-wide analysis for the melatonin trait associated genes and SNPs in dairy goat (Capra hircus) as the molecular breeding markers.

Previous studies have reported that the endogenous melatonin level is positively associated with the quality and yield of milk of cows. In the current study, a total of 34,921 SNPs involving 1,177 genes were identified in dairy goats by using the whole genome resequencing bulked segregant analysis (BSA) analysis. These SNPs have been used to match the melatonin levels of the dairy goats. Among them, 3 SNPs has been identified to significantly correlate with melatonin levels. These 3 SNPs include CC genotype 147316, GG genotype 147379 and CC genotype 1389193 which all locate in the exon regions of ASMT and MT2 genes. Dairy goats with these SNPs have approximately 5-fold-higher melatonin levels in milk and serum than the average melatonin level detected in the current goat population. If the melatonin level impacts the milk production in goats as in cows, the results strongly suggest that these 3 SNPs can serve as the molecular markers to select the goats having the improved milk quality and yield. This is a goal of our future study.

Melatonin promotes the development of sheep transgenic cloned embryos by protecting donor and recipient cells.

The yield efficiency of transgenic animal generation is relatively low[1]. To improve its efficiency has become a priority task for researchers[2]. Melatonin (N-acetyl-5-methoxytryptamine, MT) is a potent-free radical scavenger and antioxidant to protect mitochondria, lipids, protein and DNA from oxidative stress[3]. In this study, we observed that improving the quality of both donor and recipient cells by giving physiological concentration (10-7 M) of MT significantly increase the sheep transgenic embryo development in the in vitro condition. MT promotes the donor cell viability, proliferation, efficiency of monoclonal formation and the electrotransferring efficiency of fetal fibroblast cells (FFCs). The mechanistic exploration indicates that MT has the capacity for the synchronization of cell division cycle, reduction of cellular oxidative stress, apoptosis, and the increase of mitochondrial number and function. All of these render MT's ability to increase the efficiency of animal transgenic processes such as somatic cell nuclear transfer (SCNT) and electroporation. The outcomes are the increased cleavage rate and blastocyst rate of the transgenic sheep embryos after MT treatment. These beneficial effects of MT on transgenic embryo development are worth to be tested in the in vivo condition in the future.

Recent Advances of Artificial Intelligence in Cardiovascular Disease.

Cardiovascular disease (CVD) is one of the most serious health disorders with increasing prevalence and high morbidity and mortality. Although diagnosis and treatment of CVD have achieved huge breakthrough in recent years, it still needs additional enhancements, which result in the demand for new techniques. Artificial intelligence (AI) is an emerging science field that has been widely used to guide diseases diagnosis, evaluation and treatment. AI techniques are promising in CVD to explore novel pathogenic genes phenotype, guide optimal individualized therapeutic strategy, improve the management and quality of discharged patients, predict disease prognosis, and as adjuvant therapy tool. Thus, we summarize the latest application of AI techniques in clinical diagnosis, evaluation and treatment of CVD, aiming to provide novel beneficial evidence of AI and promote its application in CVD.

Metatranscriptomics and pyrosequencing facilitate discovery of potential viral natural enemies of the invasive Caribbean crazy ant, Nylanderia pubens.

BACKGROUND: Nylanderia pubens (Forel) is an invasive ant species that in recent years has developed into a serious nuisance problem in the Caribbean and United States. A rapidly expanding range, explosive localized population growth, and control difficulties have elevated this ant to pest status. Professional entomologists and the pest control industry in the United States are urgently trying to understand its biology and develop effective control methods. Currently, no known biological-based control agents are available for use in controlling N. pubens. METHODOLOGY AND PRINCIPAL FINDINGS: Metagenomics and pyrosequencing techniques were employed to examine the transcriptome of field-collected N. pubens colonies in an effort to identify virus infections with potential to serve as control agents against this pest ant. Pyrosequencing (454-platform) of a non-normalized N. pubens expression library generated 1,306,177 raw sequence reads comprising 450 Mbp. Assembly resulted in generation of 59,017 non-redundant sequences, including 27,348 contigs and 31,669 singlets. BLAST analysis of these non-redundant sequences identified 51 of potential viral origin. Additional analyses winnowed this list of potential viruses to three that appear to replicate in N. pubens. CONCLUSIONS: Pyrosequencing the transcriptome of field-collected samples of N. pubens has identified at least three sequences that are likely of viral origin and, in which, N. pubens serves as host. In addition, the N. pubens transcriptome provides a genetic resource for the scientific community which is especially important at this early stage of developing a knowledgebase for this new pest.

Physical and genetic interactions link hox function with diverse transcription factors and cell signaling proteins.

Positional information provided by Hox homeotic transcription factors is integrated with other transcription factors and cell signaling cascades in specific combinations to dictate context- and gene-specific Hox activity. Protein-protein interactions between these groups have long been hypothesized to modulate Hox functions, yielding a context-specific function. However, difficulties in applying interaction screens to potent transcription factors have limited partner identification. A yeast two-hybrid screen using transcription activation-deficient mutants of the Drosophila melanogaster Hox protein Ultrabithorax IB identified an array of interacting proteins, consisting primarily of transcription factors and components of cell signaling pathways. Interactions were confirmed with wild-type Ultrabithorax (UBX) in phage display experiments and by immunoprecipitation for a subset of partners. In vivo assays demonstrated that two Ultrabithorax IB partners, Armadillo, regulated by Wingless/WNT signaling, and the homeodomain protein Aristaless, inhibit UBX-dependent haltere development from the default wing development pathway. Therefore, transcription factors and cell signaling proteins that subdivide Hox-specified tissues can both alter Hox function in vivo and interact with the corresponding Hox protein in vitro. UBX may also modulate partner function: the pupal death phenotype induced by ectopic expression of the UBX partner Hairy required the presence of UBX. Thus, Hox.transcription factor complexes may integrate a variety of positional cues, generating the specificity and versatility required for context-dependent Hox function.

Peptide nucleic acid antisense oligomer as a therapeutic strategy against bacterial infection: proof of principle using mouse intraperitoneal infection.

Antisense oligodeoxynucleotides (ODNs) and their analogs have been successfully utilized to inhibit gene expression and bacterial growth in vitro or in cell culture. In this study, acpP-targeting antisense peptide nucleic acid (PNA) and its peptide conjugate were tested as potential antibacterial agents in two groups of experiments using a mouse model. In the first group, Escherichia coli mutant strain SM101 with a defective outer membrane was used to induce bacteremia and peritonitis in BALB/c mice by intraperitoneal (i.p.) injection. The resulting bacteremia was fatal within 48 h. A single i.p injection of 5 nmol (or more) of PNA administered 30 min before bacterial challenge significantly reduced the bacterial load in mouse blood. Reductions in serum concentrations of the proinflammatory cytokines tumor necrosis factor alpha, interleukin-1beta (IL-1beta), IL-6, and IL-12 were also observed. PNA treatment was effective in rescuing 100% of infected animals. In the second group, bacteremia in BALB/c mice was induced by i.p. injection of E. coli wild-type strain K-12. The infected mice were treated by a single intravenous injection of peptide-PNA conjugate 30 min after bacterial challenge. Treatment with the peptide-PNA conjugate significantly reduced the K-12 load, with modest reduction in cytokine concentrations. The conjugate treatment was also able to rescue up to 60% of infected animals. This report is the first demonstration of ODNs' antibacterial efficacy in an animal disease model. The ability of PNA and its peptide conjugate to inhibit bacterial growth and to prevent fatal infection demonstrates the potential for this new class of antibacterial agents.

A novel genomic approach identifies bacterial DNA-dependent RNA polymerase as the target of an antibacterial oligodeoxynucleotide, RBL1.

Rapid emergence of antibiotic-resistant bacterial pathogens limits the applicability of existing drugs, which has created an urgent need for novel antibiotics preferably with entirely new mechanisms of action. Oligodeoxynucleotides (ODNs) and their modified forms have been shown to inhibit bacterial gene expression, representing a potential for developing highly specific and efficacious antibacterial agents. In this study, a tetracycline (Tet)-inducible, randomized single-stranded DNA (ssDNA) expression library was constructed and screened for conditional growth-defective or lethal phenotypes in an Escherichia coli system. From approximately 5000 transformants screened, 12 bacterial colonies were identified with either growth-defective or lethal phenotypes. One clone, CY01, with a lethal phenotype was selected and sequenced, and the ODN sequence that it generates was designated as RBL-1. Because RBL-1 shows no significant homologies to any bacterial gene sequence, a potential RBL-1 targeting protein was isolated by affinity purification. Using mass spectrometry analysis, this protein was identified as bacterial DNA-dependent RNA polymerase (RNAP). RBL-1 was further shown to effectively inhibit RNA polymerase activity in vitro. The usage of this randomized ssDNA expression library screening technology to selectively modulate production and/or function of proteins may provide a powerful strategy in both identifying novel gene targets for antibiotic discovery and developing novel antibacterial agents.

Hox transcription factor ultrabithorax Ib physically and genetically interacts with disconnected interacting protein 1, a double-stranded RNA-binding protein.

The Hox protein family consists of homeodomain-containing transcription factors that are primary determinants of cell fate during animal development. Specific Hox function appears to rely on protein-protein interactions; however, the partners involved in these interactions and their function are largely unknown. Disconnected Interacting Protein 1 (DIP1) was isolated in a yeast two-hybrid screen of a 0-12-h Drosophila embryo library designed to identify proteins that interact with Ultrabithorax (Ubx), a Drosophila Hox protein. The Ubx.DIP1 physical interaction was confirmed using phage display, immunoprecipitation, pull-down assays, and gel retardation analysis. Ectopic expression of DIP1 in wing and haltere imaginal discs malforms the adult structures and enhances a decreased Ubx expression phenotype, establishing a genetic interaction. Ubx can generate a ternary complex by simultaneously binding its target DNA and DIP1. A large region of Ubx, including the repression domain, is required for interaction with DIP1. These more variable sequences may be key to the differential Hox function observed in vivo. The Ubx.DIP1 interaction prevents transcriptional activation by Ubx in a modified yeast one-hybrid assay, suggesting that DIP1 may modulate transcriptional regulation by Ubx. The DIP1 sequence contains two dsRNA-binding domains, and DIP1 binds double-stranded RNA with a 1000-fold higher affinity than either single-stranded RNA or double-stranded DNA. The strong interaction of Ubx with an RNA-binding protein suggests a wider range of proteins may influence Ubx function than previously appreciated.

DNA enzyme generated by a novel single-stranded DNA expression vector inhibits expression of the essential bacterial cell division gene ftsZ.

Rapid emergence of antibiotic-resistant bacterial pathogens has created urgent demand for the discovery and development of new antibacterial agents directed toward novel targets. Antisense oligodeoxynucleotides (AS-ODN) and their modified forms have been utilized to block gene expression in bacterial cells, showing potential for developing highly specific and efficacious antibacterial agents. In this study, a tetracycline-regulated expression vector was developed for generating single-stranded DNA (ssDNA) of a desired target sequence in bacterial cells. This inducible ssDNA expression vector was tested for producing a DNA enzyme designed to specifically cleave ftsZ mRNA. Our results indicate that the expressed DNA enzyme molecules not only repress ftsZ gene expression and but also inhibit bacterial cell proliferation. Although we believe that the cleavage of ftsZ mRNA by the expressed DNA enzyme molecules is responsible for the inhibitory effects on ftsZ gene expression and bacterial cell proliferation, the antisense mechanism could also be responsible for the biological effects. The ability of this ssDNA expression system to selectively modulate gene expression may provide a powerful strategy in determining the contribution of a given gene product to bacterial growth or pathogenesis and opens a new venue for developing antibacterial agents.

Transcription activation by ultrabithorax Ib protein requires a predicted alpha-helical region.

Characterization of their transcription activation domains is critical to understanding functional specificity within the Hox family of proteins. However, few Hox activation domains have been identified and none characterized in detail. In this study, promotor-reporter assays in yeast and Drosophila S2 cell culture were used to refine the boundaries of the activation domain of the Drosophila Hox protein Ultrabithorax (Ubx) and to identify critical elements within this domain. We found that residues 159-242 were sufficient for 50% function, and full transactivation capacity was achieved with inclusion of additional N-terminal sequences. Activation domain sequence and placement relative to the homeodomain differ between Ubx and other Hox proteins, consistent with the possibility that diverse activation mechanisms contribute to functional distinctions in vivo. The essential residues 159-242 in the UbxIb activation domain are predicted to contain a beta-sheet segment followed by an alpha-helix. This putative alpha-helical region was established to be necessary, but not sufficient, for transcriptional activation. Disruption of the helix by proline substitutions abolished activation function, while alteration of side chains presented on the surface of this putative helix with alanine or lysine mutations had no significant effect on activity. Collectively, these data indicate that this secondary structural element is a key component in forming an effective activation domain in the UbxIb protein. Interestingly, the alpha-helix critical for transcriptional activation is found only for Ubx orthologs from flies and not other species. The mutant Ubx proteins generated in this study have potential applications in deciphering Hox functions in vivo.