Whole genome sequencing data of Acinetobacter venetianus JKSF06 collected from Houston ship channel sediment in La Porte, Texas.

Acinetobacter venetianus is a Gram-negative, mesophilic bacterium that thrives in aquatic environments. Here, we present the whole genome sequence of A. venetianus JKSF06, isolated from sediment that was collected in La Porte, Texas, near the southern terminus of the Houston Ship Channel into the Gulf of Mexico. The JKSF06 strain harbors multiple xenobiotic gene determinants targeting environmental waste that can be found here, including petroleum hydrocarbons and n-alkanes. In addition, JKSF06 can actively degrade organophosphate phophotriesters such ethyl paraoxon. In total, the genome of JKSF06 consists of 3,462,857 bp encoding for 3173 putative proteins. The complete sequence of A. venetianus JKSF06 can be viewed under accession LSVD00000000.1 through the National Center for Biotechnology Information (NCBI).

Whole genome sequencing data of Raoultella ornithinolytica PX02 isolated from San Jacinto river sediment in Baytown, Texas.

Raoultella ornithinolytica PX02 is a Gram-negative, encapsulated bacterium, part of the Enterobacteriaceae family, emerging as a notable human pathogen. Here, we present the whole genome sequence of R. ornithinolytica PX02 isolated from San Jacinto River sediment near a Burnet Shores community in Baytown, Texas. This microorganism harbors a large 200,000 bp incF plasmid and can potentially be a significant antibiotic reservoir. The PX02 genome consists of 5,970,914 base pairs encoding approximately 5,661 functional proteins. Strain PX02 (chromosomal and plasmid) was compiled at the scaffold level and can be accessed through the National Center for Biotechnology Information database under accession NZ_NJBC00000000.1.

Genome data of Stenotrophomonas maltophilia DF07 collected from polluted river sediment reveals an opportunistic pathogen and a potential antibiotic reservoir.

Stenotrophomonas maltophilia DF07 is a gram negative bacterium isolated from polluted San Jacinto River sediment near Moncrief Park in Channelview, Texas. The genome of strain DF07 (chromosome and plasmid) was compiled at the scaffold level and can be accessed through the National Center for Biotechnology Information database under accession NZ_NJGC00000000. The DF07 genome consists of a total of 4,801,842 bp encoding for approximately 4,351 functional proteins. Approximately 86 proteins are associated with broad-spectrum antibiotic resistance, 11 are associated with bacteriocin production, and a total of 17 proteins encode for an assortment of Mycobacterium-like virulence and invasion operons. S. maltophilia DF07 is genetically similar to the nosocomial S. maltophilia strain AU12-09, but also harbors an unusually large plasmid that encodes for over 150 proteins of unknown function. Taken together, this strain is potentially an important antibiotic reservoir and its origin within a recreational park merits further study of the area.

Whole genome analysis of six organophosphate-degrading rhizobacteria reveals putative agrochemical degradation enzymes with broad substrate specificity.

Six organophosphate-degrading bacterial strains collected from farm and ranch soil rhizospheres across the Houston-metropolitan area were identified as strains of Pseudomonas putida (CBF10-2), Pseudomonas stutzeri (ODKF13), Ochrobactrum anthropi (FRAF13), Stenotrophomonas maltophilia (CBF10-1), Achromobacter xylosoxidans (ADAF13), and Rhizobium radiobacter (GHKF11). Whole genome sequencing data was assessed for relevant genes, proteins, and pathways involved in the breakdown of agrochemicals. For comparative purposes, this analysis was expanded to also include data from deposited strains in the National Center for Biotechnology Information's (NCBI) database. This study revealed Zn-dependent metallo-ß-lactamase (MBL)-fold proteins similar to OPHC2 first identified in P. pseudoalcaligenes as the likely agents of organophosphate (OP) hydrolysis in A. xylosoxidans ADAF13, S. maltophilia CBF10-1, O. anthropi FRAF13, and R. radiobacter GHKF11. A search of similar proteins within NCBI identified over 200 hits for bacterial genera and species with a similar OPHC2 domain. Taken together, we conclude from this data that intrinsic low-level OP hydrolytic activity is likely prevalent across the rhizosphere stemming from widespread OPHC2-like metalloenzymes. In addition, P. stutzeri ODKF13, P. putida CBF10-2, O. anthropi FRAF13, and R. radiobacter GHKF11 were found to harbor glycine oxidase (GO) enzymes that putatively possess low-level activity against the herbicide glyphosate. These bacterial GOs are reported to catalyze the degradation of glyphosate to α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and suggest a possible link to AMPA that can be found in glyphosate-contaminated agricultural soil. The presence of aromatic degradation proteins were also detected in five of six study strains, but are attributed primarily to components of the widely distributed ß-ketoadipate pathway found in many soil bacteria.

Genome of Pseudomonas nitroreducens DF05 from dioxin contaminated sediment downstream of the San Jacinto River waste pits reveals a broad array of aromatic degradation gene determinants.

P. nitroreducens DF05 is a Gram negative, motile, aerobic, rod-shaped and psychrotrophic bacterium that was isolated from contaminated San Jacinto River sediment near River Terrace Park in Channelview, Texas. The draft genome of strain DF05 consists of a total of 192 contigs assembled at the scaffold level totaling 6,487,527 bp and encoding for 5862 functional proteins, 1116 of which are annotated as hypothetical proteins. The bacterial chromosome has a GC content of 65.15% and contains 22 rRNA and 70 tRNA loci. In addition, approximately 142 proteins localized on the bacterial chromosome are associated with metabolism of aromatic compounds. A single plasmid approximately 95 kb in size was also detected carrying copies of RNA genes and multiple phage assembly proteins.

Whole genome of Klebsiella aerogenes PX01 isolated from San Jacinto River sediment west of Baytown, Texas reveals the presence of multiple antibiotic resistance determinants and mobile genetic elements.

Klebsiella aerogenes is a Gram-negative bacterium of the family Enterobacteriaceae which is widely distributed in water, air and soil. It also forms part of the normal microbiota found in human and animal gastrointestinal tracts. Here we report the draft genome sequence (chromosome and 1 plasmid) of K. aerogenes strain PX01 compiled at the scaffold level from 97 contigs totaling 5,262,952 bp. K. aerogenes PX01 was isolated from sediment along the northern face of Burnet Bay west of Baytown, Texas. The nucleotide sequence of this genome was deposited into NCBI GenBank under the accession NJBB00000000.

Whole genome sequencing of Microbacterium sp. AISO3 from polluted San Jacinto River sediment reveals high bacterial mobility, metabolic versatility and heavy metal resistance.

The genus Microbacterium is composed of high GC content, Gram-positive bacteria of the phylum Acintobacteria known for their antibiotic production. Microbacterium species commonly colonize agricultural rhizospheres and more infrequently have been found to colonize and infect human tissues as well. Here we report the 3,696,310 bp draft genome (chromosome and plasmids) sequence assembled at the scaffold level from 232 contigs of Microbacterium sp. strain AISO3, isolated from polluted San Jacinto River sediment in Channelview, Texas. The nucleotide sequence of this genome was deposited into NCBI GenBank under the accession NHRF00000000.

A review of the Texas, USA San Jacinto Superfund site and the deposition of polychlorinated dibenzo-p-dioxins and dibenzofurans in the San Jacinto River and Houston Ship Channel.

The San Jacinto River (SJR) waste pits that lie just under the 1-10 overpass in eastern Harris County east of Houston, Texas, USA, were created in the 1960s as dumping grounds for paper mill waste. The deposition of this waste led to accumulation of highly toxic polychlorinated dibenzo-p-dioxins and dibenzofurans (PCCDDs/PCDFs) over the course of several decades. After abandonment, the waste material eventually became submerged under the waters of the SJR, resulting in widespread environmental contamination that currently constitutes a significant health concern for eastern Harris County communities. The original waste pits were rediscovered in 2005, and the San Jacinto waste site is now a designated EPA superfund site. The objective of this review then is to discuss the history and current state of containment around the San Jacinto waste pits and analyze spatial and temporal trends in the PCDD/PCDF deposition through the SJR system from the data available. We will discuss the current exposure and health risks represented by the Superfund site and the SJR system itself, as well as the discovery of liver, kidney, brain (glioma), and retinoblastoma cancer clusters in eastern Harris County across multiple census tracts that border the Superfund site. We will also cover the two primary management options, containment versus removal of the waste from the Superfund and provide recommendations for increased monitoring of existing concentrations of polychlorinated waste in the SJR and its nearby associated communities.

Developments in alternative treatments for organophosphate poisoning.

Organophosphosphates (OPs) are highly effective acetylcholinesterase (AChE) inhibitors that are used worldwide as cheap, multi-purpose insecticides. OPs are also used as chemical weapons forming the active core of G-series and V-series chemical agents including tabun, sarin, soman, cyclosarin, VX, and their chemical analogs. Human exposure to any of these compounds leads to neurotoxic accumulation of the neurotransmitter acetylcholine, resulting in abnormal nerve function and multiple secondary health complications. Suicide from deliberate exposure to OPs is particularly prevalent in developing countries across the world and constitutes a major global health crisis. The prevalence and accessible nature of OP compounds within modern agricultural spheres and concern over their potential use in biochemical weapon attacks have incentivized both government agencies and medical researchers to enact stricter regulatory policies over their usage and to begin developing more proactive medical treatments in cases of OP poisoning. This review will discuss the research undertaken in recent years that has investigated new supplementary drug options for OP treatment and support therapy, including progress in the development of enzymatic prophylaxis.

A comparison of organophosphate degradation genes and bioremediation applications.

Organophosphates (OPs) form the bulk of pesticides that are currently in use around the world accounting for more than 30% of the world market. They also form the core for many nerve-based warfare agents including sarin and soman. The widespread use and the resultant build-up of OP pesticides and chemical nerve agents has led to the development of major health problems due to their extremely toxic interaction with any biological system that encounters them. Growing concern over the accumulation of OP compounds in our food products, in the soils from which they are harvested and in wastewater run-off has fuelled a growing interest in microbial biotechnology that provides cheap, efficient OP detoxification to supplement expensive chemical methods. In this article, we review the current state of knowledge of OP pesticide and chemical agent degradation and attempt to clarify confusion over identification and nomenclature of two major families of OP-degrading enzymes through a comparison of their structure and function. The isolation, characterization, utilization and manipulation of the major detoxifying enzymes and the molecular basis of degradation of OP pesticides and chemical nerve agents are discussed as well as the achievements and technological advancements made towards the bioremediation of such compounds.