Comparison of growth performance and tissue cobalt concentrations in beef cattle fed inorganic and organic cobalt sources.

Cobalt is an essential trace mineral required for ruminal vitamin B12 synthesis, but sources differ in ruminal microbial utilization, i.e., cobalt carbonate is poorly water soluble, whereas acetate and lactate forms are water soluble. Reports comparing organic cobalt lactate to other cobalt salts are lacking. The study objective was to determine if feeding cobalt lactate at two inclusion rates resulted in similar growth performance and tissue cobalt concentrations as the carbonate and acetate forms used in feeds. One hundred Angus cross bred steers weighing 385 ±â€…20 kg were randomly assigned to one of five treatments. Cattle were fed a basal diet plus: 1) cobalt carbonate to supply cobalt at 30 mg/steer/d, 2) cobalt acetate to supply cobalt at 30 mg/steer/d, 3) cobalt acetate to supply cobalt at 60 mg/steer/d, 4) cobalt lactate to supply cobalt at 30 mg/steer/d, and 5) cobalt lactate to supply cobalt at 60 mg/steer/d. Cattle were fed according to industry standards until body fat deposition was visually deemed to grade USDA Choice, which was 92 and 117 d for each of the 2 blocks, respectively. Steers were harvested and carcass measurements recorded along with sampling of adipose, heart, kidney, liver, and muscle for tissue cobalt concentrations. Three statistical contrasts consisted of: 1: inorganic (cobalt carbonate) vs. organic (cobalt acetate and lactate); 2: cobalt acetate vs. cobalt lactate; and 3: feeding rate of 30 vs. 60 mg/steer/d cobalt. Body weight gains, average daily gains, dry matter intake, and feed conversions were similar (P > 0.10) for steers fed all cobalt sources and feeding rates. Hot carcass weight, yield grade, back fat thickness, and ribeye area were similar (P > 0.10) among steers fed all cobalt sources and inclusion rates. Liver, kidney, muscle, and adipose cobalt concentrations were similar (P > 0.08) for steers fed inorganic vs. organic cobalt sources. Feeding cobalt lactate compared with cobalt acetate did not affect (P > 0.10) liver, kidney, heart, muscle, and adipose tissue cobalt concentrations. Feeding 60 mg/steer/d cobalt compared with 30 mg/steer/d increased (P < 0.01) liver, kidney, heart, and adipose tissue cobalt concentrations, while muscle was a tendency (P < 0.06). The study demonstrated that feeding soluble cobalt lactate, a new cobalt source, resulted in similar growth performance, carcass characteristics, and tissue cobalt concentrations when compared with cobalt acetate and carbonate.

Massilia horti sp. nov. and Noviherbaspirillum arenae sp. nov., two novel soil bacteria of the Oxalobacteraceae.

We isolated two new soil bacteria: ONC3T (from garden soil in NC, USA; LMG 31738T=NRRL B-65553T) and M1T (from farmed soil in MI, USA; NRRL B-65551T=ATCC TSD-197T=LMG 31739T) and characterized their metabolic phenotype based on Biolog, MALDI-TOF MS and fatty acid analyses, and compared 16S rRNA and whole genome sequences to other members of the Oxalobacteraceae after sequencing on an Illumina Nextera platform. Based on the results of 16S rRNA sequence analysis, ONC3T shows the highest sequence similarity to Massilia solisilvae J18T (97.8 %), Massilia terrae J11T (97.7 %) and Massilia agilis J9T (97.3 %). Strain M1T is most closely related to Noviherbaspirillum denitrificans TSA40T, Noviherbaspirillum agri K-1-15T and Noviherbaspirillum autotrophicum TSA66T (sequence identity of 98.2, 98.0 and 97.8 %, respectively). The whole genome of ONC3T has an assembled size of 5.62 Mbp, a G+C content of 63.8 mol% and contains 5104 protein-coding sequences, 56 tRNA genes and two rRNA operons. The genome of M1T has a length of 4.71 MBp, a G+C content of 63.81 mol% and includes 4967 protein-coding genes, two rRNA operons and 44 tRNA genes. Whole genome comparisons identified Massilia sp. WG5 with a 79.3 % average nucleotide identity (ANI) and 22.6 % digital DNA-DNA hybridization (dDDH), and Massilia sp. UBA11196 with 78.2 % average amino acid identity (AAI) as the most closely related species to ONC3T. M1T is most closely related to N. autotrophicum TSA66T with an ANI of 80.27 %, or N. denitrificans TSA40T with a dDDH of 22.3 %. The application of community-accepted standards such as <98.7 % in 16S sequence similarity and <95-96 % ANI or 70 % DDH support the classification of Massilia horti ONC3T and Noviherbaspirillum arenae M1T as novel species within the Oxalobacteraceae.

Duganella callida sp. nov., a novel addition to the Duganella genus, isolated from the soil of a cultivated maize field.

A Gram-negative, rod-shaped bacterium, strain Duganella callida DN04T, was isolated from the soil of a maize field in North Carolina, USA. Based on the 16S rRNA gene sequence, the most similar Duganella species are D. sacchari Sac-22T, D. ginsengisoli DCY83T, and D. radicis Sac-41T with a 97.8, 97.6, or 96.9 % sequence similarity, respectively. We compared the biochemical phenotype of DN04T to D. sacchari Sac-22T and D. zoogloeoides 115T and other reference strains from different genera within the Oxalobacteraceae and while the biochemical profile of DN04T is most similar to D. sacchari Sac-22T and other Duganella and Massilia strains, there are also distinct differences. DN04T can for example utilize turanose, N-acetyl-d-glucosamine, inosine, and l-pyroglutamic acid. The four fatty acids found in the highest percentages were C15 : 0 iso (24.6 %), C15 : 1 isoG (19.4 %), C17 : 0 iso3-OH (16.8 %), and summed feature 3 (C16:1 ⍵7c and/or C16:1 ⍵6c) (12.5 %). We also applied whole genome sequencing to determine if DN04T is a novel species. The most similar AAI (average amino acid identity) score was 70.8 % (Massilia plicata NZ CP038026T), and the most similar ANI (average nucleotide identity) score was 84.8 % (D. radicis KCTC 22382T), which indicates that DN04T is a novel species. The genome-to-genome-distance calculation (GGDC) revealed a DDH of 28.3 % to D. radicis KCTC 22382T, which is much lower than the new species threshold. Based on the morphological, phenotypic, and genomic differences, we propose Duganella callida sp. nov. as a novel species within the Duganella genus (type strain DN04T=NRRL B-65552T=LMG 31736T).

Massilia arenosa sp. nov., isolated from the soil of a cultivated maize field.

Strain MC02T, a Gram-stain-negative, rod-shaped bacterium, was isolated from field soil collected from California, USA. To examine if MC02T represents a novel species, we compared its colony morphology, 16S rRNA gene and whole genome sequence, and its metabolic phenotype using Biolog GenIII and MALDI-TOF analyses compared to reference strains. Based on 16S rRNA gene and whole genome sequencing, MC02T belongs to the genus Massilia and Massilia agri K-3-1T is the most similar strain with 96.97 % 16S rRNA gene sequence identity. MALDI-TOF analysis revealed that Massilia aerilata DSM19289T is the closest match, but the similarity score was much lower than the ≥1.7 threshold for a reliable identification at the genus level. The predominant fatty acids were summed feature 3 (C16 : 1⍵7c and/or C16 : 1⍵6c; 49.07 %) and C16 : 0 (30.01 %). The genome is 5.02 Mbp and the G+C content is 66.2 mol%. Whole genome comparisons to the closest related strains revealed an average amino acid identity value of 67.4 %, an OrthoANI similarity of 77.1 %, and a DNA-DNA-hybridization probability ≥70 %, confirming that MC02T represents a novel species. Strain MC02T can grow at pH 6 but not at pH 5, and a salt concentration of ≥1 % inhibits its growth. In contrast to other Massilia strains, MC02T can utilize turanose, inosine and l-serine. The genome of MC02T shows putative endophyte genes such as a nitrate reductase, several phosphatases, and biotin biosynthesis genes, 26 flagellar motility genes and 14 invasion and intracellular resistance genes. Based on its metabolic, physiological and genomic characteristics, we propose that strain MC02T (NRRL B-65554T=ATCC TSD-200T=LMG 31737T) represents a novel species of the genus Massilia with the name Massilia arenosa sp. nov.

Draft Genome Sequence of Massilia sp. Strain ONC3, a Novel Bacterial Species of the Oxalobacteraceae Family Isolated from Garden Soil.

From garden soil, we isolated and sequenced Massilia sp. strain ONC3, a new member of the Oxalobacteraceae within the Massilia genus. Sequence analysis showed an assembled genome size of 5,622,601 bp, with a predicted total of 5,104 protein-coding sequences, 3,194 functionally assigned genes, 2 rRNA operons, and 56 tRNAs.

Draft Genome Sequence of Massilia sp. Strain MC02, Isolated from a Sandy Loam Maize Soil.

From farmed corn soil in California, we isolated and sequenced a new member of the genus Massilia, Massilia sp. strain MC02. Massilia sp. MC02 has an assembled draft genome of 5,023,356 bp with a total of 4,790 protein-encoding genes and 3,028 predicted proteins, 47 tRNA genes, and 2 rRNA operons.

Draft Genome Sequence of Duganella sp. Strain DN04, Isolated from Cultivated Soil.

Here, we sequenced Duganella sp. strain DN04, a novel species within the genus Duganella that was isolated from a maize field in North Carolina. The assembled draft genome size is 6,562,230 bp, with a total of 6,039 protein coding sequences and 3,889 functionally assigned genes, including genes putatively involved in the colonization of plants.