Pathogenic mechanisms and therapeutic advances of small colony variants

doi:10.3969/j.issn.1674-8115.2025.06.014

Abstract

Abstract:

Small colony variants (SCVs) are unique phenotypic variants produced by bacteria such as Staphylococcus aureus under environmental selective pressure, with specific biological characteristics, including slow growth, reduced pigment synthesis, auxotrophy, enhanced drug resistance, and easier intracellular colonization and biofilm formation. In recent years, it has been increasingly recognized that SCVs play a crucial role in the chronic progression of infections and poor prognosis. SCVs exhibit significant heterogeneity with complex and diverse molecular profiles. Compared with wild-type strains, SCVs have low virulence and significantly enhanced adherence, and they can effectively evade immune system recognition and clearance. SCVs invade host cells, including macrophages, and form dormant intracellular forms, causing antimicrobial resistance. These variants can revert to wild-type bacteria when environmental conditions improve, causing persistent and refractory infections such as osteomyelitis, cystic fibrosis, and implant-associated infections. However, current treatments for SCV-related infections are limited to long-term antibiotic therapy combined with debridement of infected tissue, and understanding of SCVs, their pathogenic mechanisms, and treatments remains limited. Traditional therapies, such as rifampicin combined with vancomycin, have limited efficacy against intracellular SCVs. Novel strategies, such as targeting ATP synthase inhibitors (eg. lycopene), using nanocarrier-delivered antibiotics to enhance intracellular penetration, alkalinizing of the microenvironment, or disrupting biofilms by physical therapies, are important breakthroughs in the fight against SCV-associated infections. This paper summarizes the biological characteristics, pathogenic mechanisms, and therapeutic progress of SCVs, providing reference for research and treatment of SCV-related infections.

Key words: small colony variant (SCV), antibacterial, drug resistance, targeted infection

CLC Number:

R378.1

LIANG Xiaoning, SHI Tingwang, CHEN Yunfeng. Pathogenic mechanisms and therapeutic advances of small colony variants[J]. Journal of Shanghai Jiao Tong University (Medical Science), 2025, 45(6): 784-791.

Figures/Tables 2

TrendMD

References 47

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Colony and cellular morphology	SCV	NP
Colony appearance	Small, transparent, needle-like in shape and irregular	Round, smooth, with intact edges, convex and glossy
Pigmentation	Reduced or absent	Colorless or colored (varies by species)
Hemolytic rings	Diameter reduced or absent	S. aureus exhibits α- or β-hemolysis
Size after 24 h culture	Invisible or tiny (1/10 the size of wild-type strains)	Visible to the naked eye, 1‒3 mm or larger
Special structure	PA-SCVs: fewer flagella, increased pil and thicker capsule	Normal
Cell shape	Incomplete, branched and cross-linked	Round
Cell wall	Thickened	Relatively thin
Cytoplasm	Homogeneous	Heterogeneous (high peripheral particle density, low central density)

Colony and cellular morphology	SCV	NP
Colony appearance	Small, transparent, needle-like in shape and irregular	Round, smooth, with intact edges, convex and glossy
Pigmentation	Reduced or absent	Colorless or colored (varies by species)
Hemolytic rings	Diameter reduced or absent	S. aureus exhibits α- or β-hemolysis
Size after 24 h culture	Invisible or tiny (1/10 the size of wild-type strains)	Visible to the naked eye, 1‒3 mm or larger
Special structure	PA-SCVs: fewer flagella, increased pil and thicker capsule	Normal
Cell shape	Incomplete, branched and cross-linked	Round
Cell wall	Thickened	Relatively thin
Cytoplasm	Homogeneous	Heterogeneous (high peripheral particle density, low central density)

Carrier type	Delivery vehicle	Loaded antibiotic	SCV infection model
Lipid Nanoparticles	Poly lactic-co-glycolic acid (PLGA) nanoparticles^[40]	Rifampin	Murine macrophage Sau-SCV infection model
Silica Nanoparticles	Mesoporous silica nanoparticles (MSNPs)^[41]	Rifampin	Murine macrophage Sau-SCV infection model
Silica Nanoparticles	Organically modified (ethylene-bridged) MSNPs (MONs)^[42]	Rifampin	Murine macrophage Sau-SCV infection model
Nanogels	Dual-responsive nanogels^[20]	Gentamicin	Mouse peritonitis model
Nanogels	Gelatin-alginate composite nanogels^[43]	Enrofloxacin	Sau-SCV strain
Nanogels	Chitosan oligosaccharide-carboxymethyl cellulose composite nanogels^[44]	Tilmicosin	Sau-SCV strain
Nanogels	Composite nanogels^[45]	Florfenicol	Murine mastitis model
Nanogels	Chitosan composite nanogels^[46]	Glycyrrhizic acid	Sau-SCV strain

Carrier type	Delivery vehicle	Loaded antibiotic	SCV infection model
Lipid Nanoparticles	Poly lactic-co-glycolic acid (PLGA) nanoparticles^[40]	Rifampin	Murine macrophage Sau-SCV infection model
Silica Nanoparticles	Mesoporous silica nanoparticles (MSNPs)^[41]	Rifampin	Murine macrophage Sau-SCV infection model
Silica Nanoparticles	Organically modified (ethylene-bridged) MSNPs (MONs)^[42]	Rifampin	Murine macrophage Sau-SCV infection model
Nanogels	Dual-responsive nanogels^[20]	Gentamicin	Mouse peritonitis model
Nanogels	Gelatin-alginate composite nanogels^[43]	Enrofloxacin	Sau-SCV strain
Nanogels	Chitosan oligosaccharide-carboxymethyl cellulose composite nanogels^[44]	Tilmicosin	Sau-SCV strain
Nanogels	Composite nanogels^[45]	Florfenicol	Murine mastitis model
Nanogels	Chitosan composite nanogels^[46]	Glycyrrhizic acid	Sau-SCV strain