Conformational changes,plasma membrane penetration,and infection by human rhinovirus type 2: role of receptors and low pH

Human rhinovirus type 2 (HRV2) is internalized by members of the low-density lipoprotein (LDL) receptor (LDLR) family. It then progresses into late endosomes, where it undergoes conversion from D- to C-antigenicity at pH < 5.6. Upon uncoating, the viral RNA is transferred into the cytoplasm across the endsosomal membrane. However, C-antigenic particles fail to attach to LDLR; this raised the question of whether the virus remains attached to the receptors and is carried to late compartments or rather falls off at the higher pH in early endosomes. We therefore determined the pH dependence of virus-receptor dissociation and virus conversion to C-antigen under conditions preventing endocytosis. (35)S-HRV2 was attached to HeLa cells at 4 degrees C and incubated in buffers of pH 7.4 to 5.0; levels of native virus and C-antigenic particles remaining cell associated or having been released into the medium were determined by immunoprecipitation. At pH 6.0, HRV2 was readily released from plasma membrane receptors in its native form, whereas at pH < or = 5.4, it was entirely converted to C-antigen, which, however, only dissociated from the surface upon prolonged incubation. The antigenic conversion occurred at the same pH regardless of whether HRV2 was free in solution or bound to its receptors. These data suggest that, in vivo, the virus is no longer bound to its receptors when the antigenic conversion and uncoating occur in more acidic late endosomes. When virus was bound to HeLa cells at 4 degrees C, converted into C-antigen by exposure to pH 5.3, and subsequently warmed to 34 degrees C in the presence of bafilomycin (to prevent endosomal uncoating), viral de novo synthesis was detected. This study demonstrates for the first time that a nonenveloped virus such as HRV2 can infect from the plasma membrane when artificially exposed to low pH. This implies that the viral RNA can gain access to the cytoplasm from the plasma membrane.     

Structural Correlates of Rotavirus Cell Entry

Cell entry by non-enveloped viruses requires translocation into the cytosol of a macromolecular complex—for double-strand RNA viruses, a complete subviral particle. We have used live-cell fluorescence imaging to follow rotavirus entry and penetration into the cytosol of its ∼700 Å inner capsid particle (“double-layered particle”, DLP). We label with distinct fluorescent tags the DLP and each of the two outer-layer proteins and track the fates of each species as the particles bind and enter BSC-1 cells. Virions attach to their glycolipid receptors in the host cell membrane and rapidly become inaccessible to externally added agents; most particles that release their DLP into the cytosol have done so by ∼10 minutes, as detected by rapid diffusional motion of the DLP away from residual outer-layer proteins. Electron microscopy shows images of particles at various stages of engulfment into tightly fitting membrane invaginations, consistent with the interpretation that rotavirus particles drive their own uptake. Electron cryotomography of membrane-bound virions also shows closely wrapped membrane. Combined with high resolution structural information about the viral components, these observations suggest a molecular model for membrane disruption and DLP penetration.     

Pathway of rhinovirus disruption by soluble intercellular adhesion molecule 1 (ICAM-1): an intermediate in which ICAM-1 is bound and RNA is released.

We have examined the pathway of rhinovirus interaction with soluble intercellular adhesion molecule 1 (sICAM-1). Binding of sICAM-1 to rhinovirus serotypes 3 and 14 gives particles with sedimentation coefficients from 145 to 120S, depending on the amount of sICAM-1 bound. The formation of 120S particles is faster and more extensive at a neutral pH than at an acidic pH. A large number of receptors (> 30) can bind to human rhinovirus 3 without disruption. Disruption by sICAM-1 of rhinovirus that yields 80S particles is strongly temperature dependent and is antagonized by a low pH. Interestingly, sICAM-1 remains bound to the viral capsid after RNA is released, although in smaller amounts than those observed for the native virus. We have found heterogeneity both between and within 80S particle preparations in the VP4 content and number of bound receptors. The ability of the virus to remain bound to its receptor during the uncoating process may facilitate the transport of the viral genome into the cytoplasm in vivo.     

A single locus on human chromosome 21 directs the expression of a receptor for adenovirus type 2 in mouse A9 cells.

The receptors on human cells which mediate adsorption of adenoviruses have not been identified. We found that murine A9 cells and Chinese hamster ovary (CHO) cells failed to bind significant levels of radiolabeled adenovirus type 2 (Ad2) virions but that derivatives of these cells carrying human chromosome 21 exhibited high levels of virus binding that was specific for the viral fiber protein. G418-resistant A9 cell transformants expressing Ad2 receptors were detected at a frequency of about 10(-4) following cotransfection with high-molecular-weight DNAs from mouse cells containing human chromosome 21 and plasmid DNA containing a neomycin resistance gene. The Ad2 receptors on the transformed A9 cells were similar to those on human cells with respect to their concentration on the cell membrane, their affinity for the viral fiber protein, and their ability to direct virus into cells along a pathway leading to delivery of the viral DNA genome into the cell nucleus. Furthermore, identical human DNA fragments were present in three independent mouse cell transformants expressing Ad2 receptors, supporting the conclusion that these human DNA fragments correspond to a gene or locus on chromosome 21 that directs the expression of Ad2 receptors in these cells.     

Studies on the stimulation of cAMP metabolism in human lymphocytes by latex polymers

The purpose of this investigation was to further characterize the marked increase in intracellular cAMP which follows the interaction of human lymphocytes and latex polymers. Six distinct cell types, each of which either bind or ingest these latex particles, were studied; however, only lymphocytes responded with increases in intracellular cAMP. The initial attachment of the latex particles to the lymphocyte surface was independent of temperature, cyclic nucleotides and divalent cations in the external milieu. The subsequent cAMP response was maximal at physiologic temperatures and modulated by agents thought to alter microfilament and microtubule function. Four different types of polymers produced increases in intralymphocytic cAMP and the maximal increases were confined to particles having a mean diameter of 0.4–2.02 μm. Within this latter size range, there was a close correlation between the number of membrane-associated particles and the magnitude of the cAMP response. Similarities to the lymphocyte-lectin activation system included:

1. 1. A requirement for binding of the latex polymers to the external plasma membrane.

2. 2. A biphasic cAMP response characterized by an early rise followed by a later fall.

3. 3. Modulation of this response by pharmacologic agents which compromise microtubule and microfilament function.

In contrast to the lectin-induced activation, latex beads inhibited amino acid transport and phosphatidylinositol turnover and did not lead to later increases in DNA synthesis. These data suggest that latex polymers attach to receptors on the plasma membrane different from those responsible for lymphocyte activation, and through cAMP induce metabolic responses dissimilar to those associated with lectin activation.     

Receptor-mediated endocytosis: the intracellular journey of transferrin and its receptor

A variety of ligands and macromolecules enter cells by receptor-mediated endocytosis. Ligands bind to their receptors on the cell surface and ligand-receptor complexes are localized in specialized regions of the plasma membrane called coated pits. Coated pits invaginate and give rise to intracellular coated vesicles containing ligand-receptor complexes which are thus internalized. Transferrin, a major serum glycoprotein which transports iron into cells, enters cells by this pathway. It binds to its receptor on the cell surface, transferrin-receptor complexes cluster in coated pits and are internalized in coated vesicles. Coated vesicles then lose their clathrin coat and fuse with endosomes, an organelle with an internal pH of about 5-5.5. Most ligands dissociate from their receptors in endosomes and they finally end up in lysosomes where they are degraded, while their receptors remain bound to membrane structures and recycle to the cell surface. Transferrin has a different fate: in endosomes iron dissociates from transferrin but apotransferrin remains bound to its receptor because of its high affinity for the receptor at acid pH. Apotransferrin thus recycles back to the plasma membrane still bound to its receptor. When the ligand-receptor complex reaches the plasma membrane or a compartment at neutral pH, apotransferrin dissociates from its receptor with a half-life of 18 s because of its low affinity for its receptor at neutral pH. The receptor is then ready for a new cycle of internalization, while apotransferrin enters the circulation, reloads iron in the appropriate organs and is ready for a new cycle of iron transport.     

Functional Redundancy in HIV-1 Viral Particle Assembly

Expression of a retroviral Gag protein in mammalian cells leads to the assembly of virus particles. In vitro, recombinant Gag proteins are soluble but assemble into virus-like particles (VLPs) upon addition of nucleic acid. We have proposed that Gag undergoes a conformational change when it is at a high local concentration and that this change is an essential prerequisite for particle assembly; perhaps one way that this condition can be fulfilled is by the cooperative binding of Gag molecules to nucleic acid. We have now characterized the assembly in human cells of HIV-1 Gag molecules with a variety of defects, including (i) inability to bind to the plasma membrane, (ii) near-total inability of their capsid domains to engage in dimeric interaction, and (iii) drastically compromised ability to bind RNA. We find that Gag molecules with any one of these defects still retain some ability to assemble into roughly spherical objects with roughly correct radius of curvature. However, combination of any two of the defects completely destroys this capability. The results suggest that these three functions are somewhat redundant with respect to their contribution to particle assembly. We suggest that they are alternative mechanisms for the initial concentration of Gag molecules; under our experimental conditions, any two of the three is sufficient to lead to some semblance of correct assembly.     

Equine Rhinitis A Virus and Its Low pH Empty Particle: Clues Towards an Aphthovirus Entry Mechanism?

Equine rhinitis A virus (ERAV) is closely related to foot-and-mouth disease virus (FMDV), belonging to the genus Aphthovirus of the Picornaviridae. How picornaviruses introduce their RNA genome into the cytoplasm of the host cell to initiate replication is unclear since they have no lipid envelope to facilitate fusion with cellular membranes. It has been thought that the dissociation of the FMDV particle into pentameric subunits at acidic pH is the mechanism for genome release during cell entry, but this raises the problem of how transfer across the endosome membrane of the genome might be facilitated. In contrast, most other picornaviruses form ‘altered’ particle intermediates (not reported for aphthoviruses) thought to induce membrane pores through which the genome can be transferred. Here we show that ERAV, like FMDV, dissociates into pentamers at mildly acidic pH but demonstrate that dissociation is preceded by the transient formation of empty 80S particles which have released their genome and may represent novel biologically relevant intermediates in the aphthovirus cell entry process. The crystal structures of the native ERAV virus and a low pH form have been determined via highly efficient crystallization and data collection strategies, required due to low virus yields. ERAV is closely similar to FMDV for VP2, VP3 and part of VP4 but VP1 diverges, to give a particle with a pitted surface, as seen in cardioviruses. The low pH particle has internal structure consistent with it representing a pre-dissociation cell entry intermediate. These results suggest a unified mechanism of picornavirus cell entry.     

Auxin receptors of maize coleoptile membranes do not have ATPase activity

Membrane-localized auxin-binding sites from coleoptiles and primary leaves of Zea mays L. which may be auxin receptors can be fully solubilized by 1 to 1.5 mg of Triton X-100 per mg of membrane protein (about 1 mg per gram of original tissue fresh weight), while 70% of the basal (Mg²⁺)-ATPase and 85% of the K⁺-stimulated (Mg²⁺)-ATPase (pH 6) remain pelletable. Gel exclusion chromatography on Bio-Gel A-1.5m indicates that the solubilized receptors occur as detergent-protein micelles of about 90,000 daltons equivalent molecular weight. Solubilized ATPase activities occur (a) as very large particles excluded from the gel, and (b) as particles of a size substantially smaller than the particles that exhibit auxin binding. The auxin-binding receptor therefore appears not to be an ATPase.     

Modulation of Endotoxicity of Shigella Generalized Modules for Membrane Antigens (GMMA) by Genetic Lipid A Modifications: RELATIVE ACTIVATION OF TLR4 AND TLR2 PATHWAYS IN DIFFERENT MUTANTS*

Outer membrane particles from Gram-negative bacteria are attractive vaccine candidates as they present surface antigens in their natural context. We previously developed a high yield production process for genetically derived particles, called generalized modules for membrane antigens (GMMA), from Shigella. As GMMA are derived from the outer membrane, they contain immunostimulatory components, especially lipopolysaccharide (LPS). We examined ways of reducing their reactogenicity by modifying lipid A, the endotoxic part of LPS, through deletion of late acyltransferase genes, msbB or htrB, in GMMA-producing Shigella sonnei and Shigella flexneri strains. GMMA with resulting penta-acylated lipid A from the msbB mutants showed a 600-fold reduced ability, and GMMA from the S. sonnei ΔhtrB mutant showed a 60,000-fold reduced ability compared with GMMA with wild-type lipid A to stimulate human Toll-like receptor 4 (TLR4) in a reporter cell line. In human peripheral blood mononuclear cells, GMMA with penta-acylated lipid A showed a marked reduction in induction of inflammatory cytokines (S. sonnei ΔhtrB, 800-fold; ΔmsbB mutants, 300-fold). We found that the residual activity of these GMMA is largely due to non-lipid A-related TLR2 activation. In contrast, in the S. flexneri ΔhtrB mutant, a compensatory lipid A palmitoleoylation resulted in GMMA with hexa-acylated lipid A with ∼10-fold higher activity to stimulate peripheral blood mononuclear cells than GMMA with penta-acylated lipid A, mostly due to retained TLR4 activity. Thus, for use as vaccines, GMMA will likely require lipid A penta-acylation. The results identify the relative contributions of TLR4 and TLR2 activation by GMMA, which need to be taken into consideration for GMMA vaccine development.     

Insertion of anthrax protective antigen into liposomal membranes: effects of a receptor

Protective antigen (PA), the receptor-binding component of anthrax toxin, heptamerizes and inserts into the endosomal membrane at acidic pH, forming a pore that mediates translocation of the enzymic components of the toxin to the cytosol. When the heptameric pre-insertion form of PA (the prepore) is acidified in solution, it rapidly loses the ability to insert into membranes. To maximize insertion into model membranes, we examined two ways to bind the protein to large unilamellar vesicles (LUV). One involved attaching a His tag to the von Willebrand factor A domain of one of the PA receptors, ANTXR2, and using this protein as a bridge to bind PA to LUV containing a nickel-chelating lipid. The other involved using a His tag fused to the C terminus of PA to bind the protein directly to LUV containing the same lipid. Both ways enhanced pore formation at pH 5.0 strongly and about equally, as measured by the release of K+. Controls showed that pore formation in this system faithfully reproduced that in vivo. We also showed that binding unmodified ANTXR2 von Willebrand factor A to the prepore in solution enhanced its pore forming activity by slowing its inactivation at acidic pH. These findings indicate that an important role of PA receptors is to promote partitioning of PA into the bilayer by maintaining the prepore close to the target membrane and presumably in the optimal orientation as it undergoes the acidic pH-dependent conformational transition to the pore.     

Attachment of rat hepatocytes in vitro to substrata of serum protein, collagen, or concanavalin A.

Isolated rat hepatocytes attach to, and spread on, the surface of polystyrene tissue culture dishes in the presence of serum. The attachment is essentially complete in 30 min at 37 °C, whereas no attachment occurs at 0 °C. Dead (trypan blue-stainable) cells do not attach; hence the plating efficiency (percentage of cells attaching) is close to the percentage of intact cells in the hepatocyte suspension. Attachment in the presence of serum is relatively independent of pH, but requires divalent cations. Mg²⁺ stimulates attachment more effectively than Ca²⁺, and a combination of both cations gives maximal attachment. Cells do not attach readily to untreated dishes in the absence of serum, but attach to and spread on dishes precoated with adsorbed serum protein, concanavalin A (ConA), or a film of collagen. The attachment-promoting activity in serum is destroyed by acid treatment, by heating to 70 °C, and by protease treatment. It is therefore most probably a protein, which, like collagen and ConA, can bind to receptors on the hepatocyte surface.     

Dynamic tradeoffs in the raft-mediated entry of human immunodeficiency virus type 1 into cells

To initiate an infection human immunodeficiency virus type 1 (HIV-1) particles must first bind to receptors on the surface of their host cells, a process that eventually leads to fusion of viral and cellular membranes and release of the viral genome into the cytoplasm. Understanding the molecular mechanisms of these processes may enable the development of new anti-HIV strategies. Disagreement currently prevails on the role in virus entry of microdomains within the cellular plasma membrane known as lipid rafts. Experiments have suggested that lipid rafts, in their interactions with cellular receptors and viral particles, either promote or have minimal effect on viral entry. Here we develop a dynamic model for HIV-1 entry that enables us to identify and quantitatively assess tradeoffs that can arise from the clustering of receptors in rafts. Specifically, receptor clustering can be detrimental to the initiation of viral infection by reducing the probability that a virus particle finds its primary receptor, CD4. However, receptor clustering can also enable a virus particle, once bound, to rapidly form multivalent interactions with receptors and co-receptors that are required for virus-cell membrane fusion. We show how the resolution of such tradeoffs hinges on the level and spatial distribution of receptors and co-receptors on the cell surface, and we discuss implications of these effects for the design of therapeutics that inhibit HIV-1 entry.     

Internalization of insulin receptors and HLA antigens in human hepatoma cells.

Human HepG2 hepatoma cells express a high number of insulin receptors. Growing cells exhibit 70% of their insulin receptors on the plasma membrane. Moreover, cell-surface insulin receptors form molecular complexes with class I major histocompatibility antigens, as determined by co-immunoprecipitation of the receptors by anti-class I monoclonal antibodies. On exposure to saturating concentrations of insulin, the hormone is rapidly internalized into a Pronase-resistant compartment. Internalization of insulin is accompanied by a rapid (t1/2 = 2-3 min) redistribution of insulin receptors from the cell surface to an intracellular compartment. On removal of insulin from the medium, functional receptors recycle back to the plasma membrane, where they can bind insulin again. With chronic exposure of HepG2 cells to insulin, the initial redistribution of receptors is followed by a slow (t1/2 = 9 h) down-regulation of the receptors. Finally, notwithstanding their interaction at the cell surface, insulin receptors and class I major histocompatibility antigens are internalized at different rates and with independent regulation.     

The binding of very low density and low density lipoproteins to the plasma membrane of the hen's oocyte : A morphological study

The binding of lipoproteins to the oocyte plasma membrane of the domestic fowl (Gallus domesticus) was examined by electron microscopy in preparations of the ovarian follicle in the main phase of yolk formation. Numerous particles, 26 nm in diameter, were present on the untreated membrane. They were dissociated from the membrane by incubation at 4 °C in buffer at pH 6.2 and with heparin at pH 7.4. Added calcium was not required for binding, though the number of bound particles was reduced by treatment with EDTA. Very low density (VLD) lipoproteins from laying hen's plasma were found to bind to the denuded membrane and to correspond in size to the native particles. The results suggest that the binding characteristics are similar in quality to those determined for the binding of low density (LD) lipoproteins to mammalian cells. The oocytes, however, bound 100-fold more particles per unit length of membrane. VLD and LD lipoproteins from immature hens also adhered to the denuded membrane, although their apoprotein composition was very different from that of laying hen VLD lipoproteins. LD lipoproteins from immature hens and VLD lipoproteins from laying hens both contained apo-B, which formed about 80 and 35%, respectively, of the total apolipoproteins. Apo-VLDL-II is the other major apoprotein identified in laying-hen VLD lipoproteins. Apo-VLDL-II was not positively identified as a component of immature-hen LD lipoproteins and could only have been present as a minor component. Despite their great difference in apo-VLDL-II content, immature-hen LD lipoproteins and laying-hen VLD lipoproteins showed similar dissociation constants for binding to the oocyte plasma membrane. This evidence strongly suggests that the cell surface receptors recognize the B apoprotein of avian VLD lipoproteins.     

Interactions of diphtheria toxin B-fragment with cells. Role of amino- and carboxyl-terminal regions.

The B-fragment of diphtheria toxin binds to cell surface receptors and facilitates entry of the enzymatically active A-fragment into the cytosol. The roles of the amino- and carboxyl-terminal regions of the B-fragment in interactions with the cell membrane were studied by measuring specific binding, insertion into membranes at low pH, and formation of cation-selective channels, as well as by toxicity measurements after association with active A-fragment. Deletion of the amino-terminal 12 amino acids of the B-fragment did not affect its ability to bind to receptors and to form ion channels at low pH, whereas both abilities were strongly impaired when one more amino acid (Trp206) was removed. Replacement of the amino-terminal 31 residues with an amphipathic sequence from human apolipoprotein A1 restored receptor binding but not ion channel formation. The binding to cells was virtually abolished when 9 residues were deleted from the carboxyl terminus. Deletion of only 4 residues or extension by 12 residues did not prevent specific binding, but reduced insertion, channel formation, and toxicity. Those deletions that reduced receptor binding ability increased the trypsin sensitivity of the B-fragment. The results indicate that the amino- and carboxyl-terminal regions of diphtheria toxin B-fragment are important for receptor binding, possibly because they contribute to keep the B-fragment in a binding-competent conformation. Small alterations in the carboxyl-terminal end reduced insertion, channel formation, and toxicity more than the ability of the B-fragment to bind to cells.     

Receptor-mediated endocytosis of immunoglobulin-coated colloidal gold particles in cultured mouse peritoneal macrophages. Chloroquine and monensin inhibit transfer of the ligand from endocytic vesicles to lysosomes

Earlier studies have shown that immunoglobulin G (IgG)-coated colloidal gold particles bind to specific receptors on the macrophage surface and accumulate in coated pits. They are then internalized via endocytic vesicles and transferred to lysosomes. During this process the plasma membrane is depleted of binding sites for IgG, suggesting that both the receptor and the ligand end up in lysosomes. Here, we have examined the effects of the weak base chloroquine and the Na+-H+ ionophore monensin on endocytosis and intracellular transport of IgG-coated colloidal gold particles in cultured macrophages. The results indicate that chloroquine and monensin do not arrest uptake of IgG-coated particles bound to the cell surface. On the other hand, the drugs strongly inhibit transfer of the particles from endocytic vesicles to lysosomes, the latter marked by prior pulse-chase labeling of the cells with horseradish peroxidase. Since the main effect shared by chloroquine and monensin is to raise pH in acid compartments such as endocytic vesicles and lysosomes, the findings suggest that the transfer of IgG-coated particles into the lysosomes is a pH-dependent process. It remains to be shown whether it is the membrane fusion as such that is controlled by pH or, more specifically, the transfer of receptor-bound ligands into the lysosomes.     

The human peroxisomal targeting signal receptor, Pex5p, is translocated into the peroxisomal matrix and recycled to the cytosol

Peroxisomal targeting signals (PTSs) are recognized by predominantly cytosolic receptors, Pex5p and Pex7p. The fate of these PTS receptors following their interactions on the peroxisomal membrane with components of docking and putative translocation complexes is unknown. Using both novel and multiple experimental approaches, we show that human Pex5p does not just bind cargo and deliver it to the peroxisome membrane, but participates in multiple rounds of entry into the peroxisome matrix and export to the cytosol independent of the PTS2 import pathway. This unusual shuttling mechanism for the PTS1 receptor distinguishes protein import into peroxisomes from that into most other organelles, with the exception of the nucleus.     

Molecular determinants underlying the formation of stable intracellular G protein-coupled receptor-beta-arrestin complexes after receptor endocytosis*

beta-Arrestins bind agonist-activated G protein-coupled receptors (GPCRs) and mediate their desensitization and internalization. Although beta-arrestins dissociate from some receptors at the plasma membrane, such as the beta2 adrenergic receptor, they remain associated with other GPCRs and internalize with them into endocytic vesicles. Formation of stable receptor-beta-arrestin complexes that persist inside the cell impedes receptor resensitization, and the aberrant formation of these complexes may play a role in GPCR-based diseases (Barak, L. S., Oakley, R. H., Laporte, S. A., and Caron, M. G. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 93-98). Here, we investigate the molecular determinants responsible for sustained receptor/beta-arrestin interactions. We show in real time and in live human embryonic kidney (HEK-293) cells that a beta-arrestin-2-green fluorescent protein conjugate internalizes into endocytic vesicles with agonist-activated neurotensin-1 receptor, oxytocin receptor, angiotensin II type 1A receptor, and substance P receptor. Using receptor mutagenesis, we demonstrate that the ability of beta-arrestin to remain associated with these receptors is mediated by specific clusters of serine and threonine residues located in the receptor carboxyl-terminal tail. These clusters are remarkably conserved in their position within the carboxyl-terminal domain and serve as primary sites of agonist-dependent receptor phosphorylation. In addition, we identify a beta-arrestin mutant with enhanced affinity for the agonist-activated beta2-adrenergic receptor that traffics into endocytic vesicles with receptors that lack serine/threonine clusters and normally dissociate from wild-type beta-arrestin at the plasma membrane. By identifying receptor and beta-arrestin residues critical for the formation of stable receptor-beta-arrestin complexes, these studies provide novel targets for regulating GPCR responsiveness and treating diseases resulting from abnormal GPCR/beta-arrestin interactions.     

Ubiquitin-coated nanodiamonds bind to autophagy receptors for entry into the selective autophagy pathway

Selective macroautophagy/autophagy plays a pivotal role in the processing of foreign pathogens and cellular components to maintain homeostasis in human cells. To date, numerous studies have demonstrated the uptake of nanoparticles by cells, but their intracellular processing through selective autophagy remains unclear. Here we show that carbon-based nanodiamonds (NDs) coated with ubiquitin (Ub) bind to autophagy receptors (SQSTM1 [sequestosome 1], OPTN [optineurin], and CALCOCO2/NDP52 [calcium binding and coiled-coil domain 2]) and are then linked to MAP1LC3/LC3 (microtubule-associated protein 1 light chain 3) for entry into the selective autophagy pathway. NDs are ultimately delivered to lysosomes. Ectopically expressed SQSTM1-green fluorescence protein (GFP) could bind to the Ub-coated NDs. By contrast, the Ub-associated domain mutant of SQSTM1 (ΔUBA)-GFP did not bind to the Ub-coated NDs. Chloroquine, an autophagy inhibitor, prevented the ND-containing autophagosomes from fusing with lysosomes. Furthermore, autophagy receptors OPTN and CALCOCO2/NDP52, involved in the processing of bacteria, were found to be involved in the selective autophagy of NDs. However, ND particles located in the lysosomes of cells did not induce mitotic blockage, senescence, or cell death. Single ND clusters in the lysosomes of cells were observed in the xenografted human lung tumors of nude mice. This study demonstrated for the first time that Ub-coated nanoparticles bind to autophagy receptors for entry into the selective autophagy pathway, facilitating their delivery to lysosomes.