Article · Wikipedia archive · Last revised Jun 17, 2026

Kocuria rosea

Kocuria rosea is a gram-positive bacteria that is catalase-positive and oxidase-positive. It has a coccus shape that occurs in the tetrad arrangement and is a strict aerobe that grows best from 25 to 37 °C. K. rosea has also been found to cause urinary tract infections in people with weakened immune systems.

Last revised
Jun 17, 2026
Read time
≈ 3 min
Length
787 w
Citations
15
Source
Wikipedia ↗
Kocuria rosea
Scientific classification Edit this classification
Domain: Bacteria
Kingdom: Bacillati
Phylum: Actinomycetota
Class: Actinomycetes
Order: Micrococcales
Family: Micrococcaceae
Genus: Kocuria
Species:
K. rosea
Binomial name
Kocuria rosea
(Flügge 1886) Stackebrandt et al. 19951
Type strain
ATCC 186
CCM 679
CCUG 4312
CIP 71.15
DSM 20447
IEGM 394
IFO 3768
JCM 11614
LMG 14224
NBRC 3768
NCTC 7523
NRRL B-2977
VKM B-1823
Synonyms1
  • Pelczaria aurantia Poston 1994
  • Deinococcus erythromyxa (ex Chester 1901) Brooks and Murray 1981
  • Micrococcus roseus Flügge 1886 (Approved Lists 1980)
  • Kocuria erythromyxa (Brooks and Murray 1981) Rainey et al. 1997

Kocuria rosea is a gram-positive bacteria that is catalase-positive and oxidase-positive. It has a coccus shape that occurs in the tetrad arrangement and is a strict aerobe that grows best from 25 to 37 °C.2 K. rosea has also been found to cause urinary tract infections in people with weakened immune systems.3

The normal habitat for this Kocuria species is skin, soil, and water.4 It derives its name from the carotenoid pigment that it secretes.5 Isolated colonies on a TSA plate are circular, 1.0–1.5 mm in size, slightly convex, smooth, and pink in color.6

Metabolism

K. rosea has been found to be able to biodegrade malachite green, azo dyes, triphenylmethane, as well as some other industrial dyes.7 Due to its ability to biodegrade these dyes, it has become of interest as a potential means to biodegrade dyes that would otherwise take a long time to naturally break down. It also has been found to have the ability to perform keratin hydrolysis through the production of keratinases.8

  • Kocuria rosea* strain DBUPL4, isolated from soil in the Guassa Community Conservation Area (GCCA) in Ethiopia, demonstrated extracellular amylase production. On starch agar it produced a clear hydrolysis halo of approximately 15 mm following iodine flooding, indicating active starch degradation. 9

Multiple strains of K. rosea have been reported to grow poorly or be inhibited on Simmons’ citrate agar, likely due to an interaction with the bromothymol blue pH indicator. 10

Stress tolerance

Growth studies on Kocuria rosea strain DBUPL4 showed optimal proliferation between 25–30 °C, with peak growth at 30 °C and markedly reduced growth above 40 °C. Other studies report a broader temperature growth window ranging from 25–37 °C depending on strain variation.1112

An environmental isolate, K. rosea strain MG2, was recovered from a naturally radioactive alkaline hot spring and exhibited tolerance to multiple physical and chemical stresses. This strain grew optimally at approximately pH 9.2, survived up to 15% NaCl, resisted UV-C irradiation at intensities normally lethal to most non-extremophilic bacteria, tolerated oxidative stress, and maintained viability after 28-day desiccation. These properties indicate that some K. rosea strains may possess polyextremotolerance, a trait common among many Actinobacteria.13

Certain strains of K. rosea (including strains 394 and 397) have been reported to carry an RM gene strongly homologous to rifampicin-resistance determinants, suggesting potential rifampicin resistance.14

References

References

  1. Parte, A.C. "Kocuria". LPSN.
  2. Leboffe, Michael J.; Burton E. Pierce. The Photographic Atlas for the Microbiology Laboratory (3rd ed.).
  3. "Kocuria rosea". vumicro.com. Retrieved 9 November 2017.
  4. Sneath, Peter (1986). Bergeys Manual of Systemic Bacteriology Volume 2.
  5. Jagannadham, MV; M.K. Chattopadhyay; S. Shivaji (1996). "The major carotenoid pigment of a psychrotrophic Micrococcus roseus strain: Fluorescence properties of the pigment and its binding to membranes". Biochemical and Biophysical Research Communications. 220 (3). Elsevier Publishing: 724–728. Bibcode:1996BBRC..220..724J. doi:10.1006/bbrc.1996.0471. PMID 8607832.
  6. Holt, John. Bergeys Manual of Determinative Bacteriology (9th ed.).
  7. Parshetti, Ganesh; Kalme, Satish; Saratale, Ganesh; Govindwar, Sanjay (August 8, 2006). "Biodegradation of Malachite Green by Kocuria rosea MTCC 1532". www.researchgate.net.
  8. Bernal, C.; Vidal, L.; Valdivieso, E.; Coello, N. (2003-04-01). "Keratinolytic activity of Kocuria rosea". World Journal of Microbiology and Biotechnology. 19 (3): 255–261. Bibcode:2003WJMB...19..255B. doi:10.1023/A:1023685621215. ISSN 0959-3993. S2CID 83778784.
  9. Kim, S.-H.; Kim, W.-J.; Ryu, J.; Yerefu, Y.; Tesfaw, A. (2025). "Amylase production by the new strains of Kocuria rosea and Micrococcus endophyticus isolated from soil in the Guassa Community Conservation Area". Fermentation. 11 (4): 211. doi:10.3390/fermentation11040211.
  10. Stoica, C. "Kocuria rosea". ABIS Encyclopedia. Retrieved 2025-12-03.
  11. Kim, S.-H.; Kim, W.-J.; Ryu, J.; Yerefu, Y.; Tesfaw, A. (2025). "Amylase production by the new strains of Kocuria rosea and Micrococcus endophyticus isolated from soil in the Guassa Community Conservation Area". Fermentation. 11 (4): 211. doi:10.3390/fermentation11040211.
  12. Stoica, C. "Kocuria rosea". ABIS Encyclopedia. Retrieved 2025-12-03.
  13. Shivlata, L.; Satyanarayana, T. (2015). "Thermophilic and alkaliphilic Actinobacteria: biology and potential applications". Frontiers in Microbiology. 6: 1014. Bibcode:2015FrMic...601014S. doi:10.3389/fmicb.2015.01014. PMC 4585250. PMID 26441937.
  14. Zorov, D. B.; Popova, E. M.; Zakharevich, M. V. (2025). "Distribution of Antibiotic Resistance Genes in Kocuria species". Antibiotics. 14 (10): 1041. doi:10.3390/antibiotics14101041. PMC 12562059. PMID 41148733.
External links