Efficient Internalization of MHC I Requires Lysine‐11 and Lysine‐63 Mixed Linkage Polyubiquitin Chains

The downregulation of cell surface receptors by endocytosis is a fundamental requirement for the termination of signalling responses and ubiquitination is a critical regulatory step in receptor regulation. The K5 gene product of Kaposi's sarcoma‐associated herpesvirus is an E3 ligase that ubiquitinates and downregulates several cell surface immunoreceptors, including major histocompatibility complex (MHC) class I molecules. Here, we show that K5 targets the membrane proximal lysine of MHC I for conjugation with mixed linkage polyubiquitin chains. Quantitative mass spectrometry revealed an increase in lysine‐11, as well as lysine‐63, linked polyubiquitin chains on MHC I in K5‐expressing cells. Using a combination of mutant ubiquitins and MHC I molecules expressing a single cytosolic lysine residue, we confirm a functional role for lysines‐11 and ‐63 in K5‐mediated MHC I endocytosis. We show that lysine‐11 linkages are important for receptor endocytosis, and that complex mixed linkage polyubiquitin chains are generated in vivo.     

Class I Rab11‐family interacting proteins are binding targets for the Rab14 GTPase

Background information. Rab11 and Rab14 are two related Rab GTPases that are believed to function in endosomal recycling and Golgi/endosome transport processes. We, and others, have identified a group of proteins that interact with Rab11 and function as Rab11 effectors, known as the Rab11‐FIPs (family interacting proteins). This protein family has been sub‐classified into two groups—class I FIPs [FIP2, RCP (Rab coupling protein) and Rip11 (Rab11‐interacting protein)] and class II FIPs (FIP3 and FIP4). Results. In the present study we identify the class I FIPs as dual Rab‐binding proteins by demonstrating that they also interact with Rab14 in a GTP‐dependent manner. We show that these interactions are specific for the class I FIPs and that they occur via their C‐terminal regions, which encompass the previously described RBD (Rab11‐binding domain). Furthermore, we show that Rab14 significantly co‐localizes with the TfnR (transferrin receptor) and that Rab14 Q70L co‐localizes with Rab11a and with the class I FIPs on the ERC (endosomal recycling compartment) during interphase. Additionally, we show that during cytokinesis Rab14 localizes to the cleavage furrow/midbody. Conclusions. The data presented in the present study, which identifies the class I FIPs as the first putative effector proteins for the Rab14 GTPase, indicates greater complexity in the Rab‐binding specificity of the class I FIP proteins.     

Expanding the ubiquitin code through post‐translational modification

Ubiquitylation is among the most prevalent post‐translational modifications (PTMs) and regulates numerous cellular functions. Interestingly, ubiquitin (Ub) can be itself modified by other PTMs, including acetylation and phosphorylation. Acetylation of Ub on K6 and K48 represses the formation and elongation of Ub chains. Phosphorylation of Ub happens on multiple sites, S57 and S65 being the most frequently modified in yeast and mammalian cells, respectively. In mammals, the PINK1 kinase activates ubiquitin ligase Parkin by phosphorylating S65 of Ub and of the Parkin Ubl domain, which in turn promotes the amplification of autophagy signals necessary for the removal of damaged mitochondria. Similarly, TBK1 phosphorylates the autophagy receptors OPTN and p62 to initiate feedback and feedforward programs for Ub‐dependent removal of protein aggregates, mitochondria and pathogens (such as Salmonella and Mycobacterium tuberculosis). The impact of PINK1‐mediated phosphorylation of Ub and TBK1‐dependent phosphorylation of autophagy receptors (OPTN and p62) has been recently linked to the development of Parkinson's disease and amyotrophic lateral sclerosis, respectively. Hence, the post‐translational modification of Ub and its receptors can efficiently expand the Ub code and modulate its functions in health and disease.     

Recruitment of TBK1 to cytosol‐invading Salmonella induces WIPI2‐dependent antibacterial autophagy

Mammalian cells deploy autophagy to defend their cytosol against bacterial invaders. Anti‐bacterial autophagy relies on the core autophagy machinery, cargo receptors, and “eat‐me” signals such as galectin‐8 and ubiquitin that label bacteria as autophagy cargo. Anti‐bacterial autophagy also requires the kinase TBK1, whose role in autophagy has remained enigmatic. Here we show that recruitment of WIPI2, itself essential for anti‐bacterial autophagy, is dependent on the localization of catalytically active TBK1 to the vicinity of cytosolic bacteria. Experimental manipulation of TBK1 recruitment revealed that engagement of TBK1 with any of a variety of Salmonella‐associated “eat‐me” signals, including host‐derived glycans and K48‐ and K63‐linked ubiquitin chains, suffices to restrict bacterial proliferation. Promiscuity in recruiting TBK1 via independent signals may buffer TBK1 functionality from potential bacterial antagonism and thus be of evolutionary advantage to the host.     

A single MIU motif of MINDY‐1 recognizes K48‐linked polyubiquitin chains

The eight different types of ubiquitin (Ub) chains that can be formed play important roles in diverse cellular processes. Linkage‐selective recognition of Ub chains by Ub‐binding domain (UBD)‐containing proteins is central to coupling different Ub signals to specific cellular responses. The motif interacting with ubiquitin (MIU) is a small UBD that has been characterized for its binding to monoUb. The recently discovered deubiquitinase MINDY‐1/FAM63A contains a tandem MIU repeat (tMIU) that is highly selective at binding to K48‐linked polyUb. We here identify that this linkage‐selective binding is mediated by a single MIU motif (MIU2) in MINDY‐1. The crystal structure of MIU2 in complex with K48‐linked polyubiquitin chains reveals that MIU2 on its own binds to all three Ub moieties in an open conformation that can only be accommodated by K48‐linked triUb. The weak Ub binder MIU1 increases overall affinity of the tMIU for polyUb chains without affecting its linkage selectivity. Our analyses reveal new concepts for linkage selectivity and polyUb recognition by UBDs.     

Distinct Sets of Rab6 Effectors Contribute to ZW10‐ and COG‐Dependent Golgi Homeostasis

The organization of the Golgi apparatus is determined in part by the interaction of Rab proteins and their diverse array of effectors. Here, we used multiple approaches to identify and characterize a small subset of effectors that mimicked the effects of Rab6 on Golgi ribbon organization. In a visual‐based, candidate protein screen, we found that the individual depletion of any of three Rab6 effectors, myosin IIA (MyoIIA), Kif20A and Bicaudal D (BicD), was sufficient to suppress Golgi ribbon fragmentation/dispersal coupled to retrograde tether proteins in a manner paralleling Rab6. MyoIIA and Kif20A depletions were pathway selective and suppressed ZW10‐dependent Golgi ribbon fragmentation/dispersal only whereas BicD depletion, like Rab6, suppressed both ZW10‐ and COG‐dependent Golgi ribbon fragmentation. The MyoIIA effects could be produced in short‐term assays by the reversible myosin inhibitor, blebbistatin. At the electron microscope level, the effects of BicD‐depletion mimicked many of those of Rab6‐depletion: longer and more continuous Golgi cisternae and a pronounced accumulation of coated vesicles. Functionally, BicD‐depleted cells were inhibited in transport of newly synthesized VSV‐G protein to the cell surface. In summary, our results indicate small, partially overlapping subsets of Rab6 effectors are differentially important to two tether‐dependent pathways essential to Golgi organization and function.      

Bartonella quintana type IV secretion effector BepE‐induced selective autophagy by conjugation with K63 polyubiquitin chain

Bartonella effector proteins (named Beps) are substrates of VirB type IV secretion system for translocation into host cells evolved in Bartonella spp. Among these, BepE has been shown to protect cells from fragmentation effects triggered by other Beps and to promote in vivo dissemination of bacteria from the dermal site of inoculation to the bloodstream. Bacterial pathogens secreted effectors to modulate the interplay with host autophagy, either to combat autophagy to escape its bactericidal effect or to exploit autophagy to benefit intracellular replication. Here, we reported a distinct phenotype that selective autophagy in host cells is activated as a countermeasure, to attack BepE via conjugation with K63 polyubiquitin chain on BepE. We found that ectopic expression of Bartonella quintana BepE specifically induced punctate structures that colocalised with an autophagy marker (LC3‐II) in host cells, in addition to filopodia and membrane ruffle formation. Two tandemly arranged B artonella Intracellular Delivery (BID) domains in the BepE C‐terminus, where ubiquitination of sister pairs of lysine residues was confirmed, were essential to activate host cell autophagy. Multiple polyubiquitin chain linkages of K27, K29, K33, and K63 were found to be conjugated at sites of K222 and K365 on BepE, of which K63 polyubiquitination on BepE K365 determined the selective autophagy (p62/SQSTM1 positive autophagy) independent of the PI3K pathway. Colocalisation of BepE with LAMP1 confirmed the maturation of BepE‐induced autophagosomes in which BepE were targeted for degradation. Moreover, host cells employed selective autophagy to counter‐attack BepE to rescue cells from BepE‐induced endocytosis deficiency.     

Rab33b and Rab6 are Functionally Overlapping Regulators of Golgi Homeostasis and Trafficking

We used multiple approaches to investigate the coordination of trans and medial Rab proteins in the regulation of intra‐Golgi retrograde trafficking. We reasoned that medially located Rab33b might act downstream of the trans Golgi Rab, Rab6, in regulating intra‐Golgi retrograde trafficking. We found that knockdown of Rab33b, like Rab6, suppressed conserved oligomeric Golgi (COG) complex‐ or Zeste White 10 (ZW10)‐depletion induced disruption of the Golgi ribbon in HeLa cells. Moreover, efficient GTP‐restricted Rab6 induced relocation of Golgi enzymes to the endoplasmic reticulum (ER) was Rab33b‐dependent, but not vice versa, suggesting that the two Rabs act sequentially in an intra‐Golgi Rab cascade. In support of this hypothesis, we found that overexpression of GTP‐Rab33b induced the dissociation of Rab6 from Golgi membranes in vivo. In addition, the transport of Shiga‐like toxin B fragment (SLTB) from the trans to cis Golgi and ER required Rab33b. Surprisingly, depletion of Rab33b had little, if any, immediate effect on cell growth and multiplication. Furthermore, anterograde trafficking of tsO45G protein through the Golgi apparatus was normal. We suggest that the Rab33b/Rab6 regulated intra‐Golgi retrograde trafficking pathway must coexist with other Golgi trafficking pathways. In conclusion, we provide the first evidence that Rab33b and Rab6 act to coordinate a major intra‐Golgi retrograde trafficking pathway. This coordination may have parallels with Rab conversion/cascade events that regulate endosome, phagosome and exocytic processes.     

Regulation of Glucose Transporter SGLT1 by Ubiquitin Ligase Nedd4‐2 and Kinases SGK1, SGK3, and PKB

Objectives : Serum‐ and glucocorticoid‐inducible kinase 1 (SGK1) inhibits the ubiquitin ligase neuronal cell expressed developmentally downregulated 4‐2 (Nedd4‐2), which retards the retrieval of the epithelial Na⁺ channel ENaC. Accordingly, SGK1 enhances ENaC abundance in the cell membrane. The significance of this effect is shown by an association of an E8CC/CT;I6CC polymorphism in the SGK1 gene with increased blood pressure. However, strong expression of SGK1 in enterocytes not expressing ENaC points to further functions of SGK1. This study was performed to test for regulation of Na⁺‐coupled glucose transporter 1 (SGLT1) by Nedd4‐2, SGK1, and/or the related kinases SGK3 and PKB. Additional studies searched for an association of the SGK1 gene with BMI. Research Methods and Procedures : mRNA encoding SGLT1, wild‐type Nedd4‐2, inactive ^C938SNedd4‐2, wild type SGK1, constitutively active ^S422DSGK1 or inactive ^K127NSGK1, wild‐type SGK3, and constitutively active ^T308DS473DPKB or inactive ^T308AS473APKB were injected into Xenopus oocytes, and glucose transport was quantified from glucose‐induced current (I_glc). BMI was determined in individuals with or without the E8CC/CT;I6CC polymorphism. Results: I_glc was significantly decreased by coexpression of Nedd4‐2 but not of ^C938SNedd4‐2. Coexpression of SGK1, ^S422DSGK1, SGK3, or ^T308DS473DPKB, but not of ^K127NSGK1 or ^T308AS473APKB, enhanced I_glc and reversed the effect of Nedd4‐2. SGK1 and SGK3 phosphorylated Nedd4‐2. Deletion of the SGK/PKB phosphorylation sites in Nedd4‐2 blunted the kinase effects. BMI was significantly (p < 0.008) greater in individuals with the E8CC/CT;I6CC polymorphism than in individuals without. Discussion : Overactivity of SGK1 may lead not only to excessive ENaC activity and hypertension but also to enhanced SGLT1 activity and obesity.     

K63‐specific deubiquitination by two JAMM/MPN+ complexes: BRISC‐associated Brcc36 and proteasomal Poh1

An unusual deubiquitinating (DUB) activity exists in HeLa cell extracts that is highly specific for cleaving K63‐linked but not K48‐linked polyubiquitin chains. The activity is insensitive to both N‐ethyl‐maleimide and ubiquitin aldehyde, indicating that it lacks an active site cysteine residue, and gel filtration experiments show that it resides in a high molecular weight (～600 kDa) complex. Using a biochemical approach, we found that the K63‐specific DUB activity co‐fractionated through seven chromatographic steps with three multisubunit complexes: the 19S (PA700) portion of the 26S proteasome, the COP9 signalosome (CSN) and a novel complex that includes the JAMM/MPN+ domain‐containing protein Brcc36. When we analysed the individual complexes, we found that the activity was intrinsic to PA700 and the Br cc36 is opeptidase c omplex (BRISC), but that the CSN‐associated activity was due entirely to an interaction with Brcc36. None of the complexes cleave K6, K11, K29, K48 or α‐linked polyubiquitin, but they do cleave K63 linkages within mixed‐linkage chains. Our results suggest that specificity for K63‐linked polyubiquitin is a common property of the JAMM/MPN+ family of DUBs.     

RAC1mutation is not a predictive biomarker for PI3’‐kinase‐β‐selective pathway‐targeted therapy

Mutational activation of RAC1 is detected in ~7% of cutaneous melanoma, with the most frequent mutation (RAC1^C85T) encoding for RAC1^P29S. RAC1^P29S is a fast‐cycling GTPase that leads to accumulation of RAC1^P29S‐GTP, which has potentially pleiotropic regulatory functions in melanoma cell signaling and biology. However, the precise mechanism by which mutationally activated RAC1^P29S propagates its pro‐tumorigenic effects remains unclear. RAC1‐GTP is reported to activate the beta isoform of PI3’‐kinase (PIK3CB/PI3Kβ) leading to downstream activation of PI3’‐lipid signaling. Hence, we employed both genetic and isoform‐selective pharmacological inhibitors to test if RAC1^P29S propagates its oncogenic signaling in melanoma through PI3Kβ. We observed that RAC1^P29S‐expressing melanoma cells were largely insensitive to inhibitors of PI3Kβ. Furthermore, RAC1^P29S melanoma cell lines showed variable sensitivity to pan‐class 1 (α/β/γ/δ) PI3’‐kinase inhibitors, suggesting that RAC1‐mutated melanoma cells may not rely on PI3’‐lipid signaling for their proliferation. Lastly, we observed that RAC1^P29S‐expressing cell lines also showed variable sensitivity to pharmacological inhibition of the RAC1 → PAK1 signaling pathway, questioning the relevance of inhibitors of this pathway for the treatment of patients with RAC1‐mutated melanoma.     

14‐3‐3ζ binds to and stabilizes phospho‐beclin 1S295 and induces autophagy in hepatocellular carcinoma cells

Data from The Cancer Genome Atlas (TCGA) indicate that the expression levels of 14‐3‐3ζ and beclin 1 (a key molecule involved in cellular autophagy) are up‐regulated and positively correlated with each other (R = .5, P < .05) in HCC tissues. Chemoresistance developed in hepatoma cancer cells is associated with autophagy initiation. This study aimed to explore 14‐3‐3ζ’s role in regulating autophagy in HCC cells, with a focus on beclin 1. The co‐localization of 14‐3‐3ζ and beclin 1 was detectable in primary HCC tissues. To simulate in vivo tumour microenvironment (hypoxia), CSQT‐2 and HCC‐LM3 cells were exposed to 2% oxygen for 24 hours. The protein levels of 14‐3‐3ζ and phospho‐beclin 1^S295 peaked at 12 hours following hypoxia. Meanwhile, the strongest autophagy flux occurred: LC3II was increased, and p62 was decreased significantly. By sequencing the coding area of BECN 1 gene of CSQT‐2 and HCC‐LM3 cells, we found that the predicted translational products of BECN 1 gene contained RLPS²⁹⁵VP (R, arginine; L, leucine; P, proline; S, serine; V, valine), a classic 14‐3‐3ζ binding motif. CO‐IP results confirmed that 14‐3‐3ζ bound to beclin 1, and this connection was markedly weakened when S²⁹⁵ was mutated into A²⁹⁵ (alanine). Further, 14‐3‐3ζ overexpression prevented phospho‐beclin 1^S295 from degradation and enhanced its binding to VPS34, whilst its knockdown accelerated the degradation. Additionally, 14‐3‐3ζ enhanced the chemoresistance of HCC cells to cis‐diammined dichloridoplatium by activating autophagy. Our work reveals that 14‐3‐3ζ binds to and stabilizes phospho‐beclin 1^S295 and induces autophagy in HCC cells to resist chemotherapy.     

Spatiotemporal Resolution of Rab9 and CI‐MPR Dynamics in the Endocytic Pathway

Rab9 is a small GTPase that localizes to the trans‐Golgi Network (TGN) and late endosomes. Its main function has long been connected to the recycling of mannose‐6‐phosphate receptors (MPRs). However, recent studies link Rab9 also to autophagy and lysosome biogenesis. In this paper, using confocal imaging, we characterize for the first time the live dynamics of the Rab9 constitutively active mutant, Rab9Q66L. We find that it localizes predominantly to late endosomes and that its expression in HeLa cells disperses TGN46 and cation‐independent (CI‐MPR) away from the Golgi yet, has no effect on the retrograde transport of CI‐MPR. We also show that CI‐MPR and Rab9 enter the endosomal pathway together at the transition stage between early, Rab5‐positive, and late, Rab7a‐positive, endosomes. CI‐MPR localizes transiently to separate domains on these endosomes, where vesicles carrying CI‐MPR attach and detach within seconds. Taken together, our results demonstrate that Rab9 mediates the delivery of CI‐MPR to the endosomal pathway, entering the maturing endosome at the early‐to‐late transition.      

S‐ to N‐Acyl transfer in S‐acylcysteine isopeptides via 9‐, 10‐, 12‐, and 13‐membered cyclic transition states

S‐Acyl cysteine peptides containing α‐, β‐ or γ‐amino acid residues undergo long‐range S‐ to N‐acyl transfer to give analogs of native tripeptides and tetrapeptides containing additional carbon atoms in the chain. The ease of intramolecular S → N‐acyl transfer relative to intermolecular transacylation is favored increasingly for 9 < 12 < 13 ~ 10‐membered cyclic transition states; the observed order is explained on conformational and intermolecular interaction considerations. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

An improved synthesis of (2S, 4S)‐ and (2S, 4R)‐2‐amino‐4‐methyldecanoic acids: assignment of the stereochemistry of culicinins

An improved synthesis of (2S, 4S)‐ and (2S, 4R)‐2‐amino‐4‐methyldecanoic acids was accomplished using a glutamate derivative as starting material and Evans' asymmetric alkylation as the decisive step. The NMR data of the two diastereomers were measured and compared with those of the natural product. As a result, the stereochemistry of this novel amino acid unit in culicinins was assigned as (2S, 4R). Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Enantiopure 4‐oxazolin‐2‐ones and 4‐methylene‐2‐oxazolidinones as chiral building blocks in a divergent asymmetric synthesis of heterocycles

Enantiopure 3‐((R)‐ and 3‐((S)‐1‐phenylethyl)‐4‐oxazoline‐2‐ones were evaluated as chiral building blocks for the divergent construction of heterocycles with stereogenic quaternary centers. The N‐(R)‐ or N‐(S)‐1‐phenylethyl group of these compounds proved to be an efficient chiral auxiliary for the asymmetric induction of the 4‐ and 5‐positions of the 4‐oxazolin‐2‐one ring through thermal and MW‐promoted nucleophilic conjugated addition to Michael acceptors and alkyl halides. The resulting adducts were transformed via a cascade process into fused six‐membered carbo‐ and heterocycles. The structure of the reaction products depended on the electrophiles and reaction conditions used. Alternative isomeric 4‐methylene‐2‐oxazolidinones served as chiral precursors for a versatile and divergent approach to highly substituted cyclic carbamates. DFT quantum calculations showed that the formation of bicyclic pyranyl compounds was generated by a diastereoselective concerted hetero‐Diels‐Alder cycloaddition.     

The Anaplasma phagocytophilum‐occupied vacuole selectively recruits Rab‐GTPases that are predominantly associated with recycling endosomes

Anaplasma phagocytophilum is an obligate intracellular bacterium that infects neutrophils to reside within a host cell‐derived vacuole. The A. phagocytophilum‐occupied vacuole (ApV) fails to mature along the endocytic pathway and is non‐fusogenic with lysosomes. Rab GTPases regulate membrane traffic. To better understand how the bacterium modulates the ApV's selective fusogencity, we examined the intracellular localization of 20 green fluorescent protein (GFP) or red fluorescent protein (RFP)‐tagged Rab GTPases in A. phagocytophilum‐infected HL‐60 cells. GFP‐Rab4A, GFP‐Rab10, GFP‐Rab11A, GFP‐Rab14, RFP‐Rab22A and GFP‐Rab35, which regulate endocytic recycling, and GFP‐Rab1, which mediates endoplasmic reticulum to Golgi apparatus trafficking, localize to the ApV. Fluorescently tagged Rabs are recruited to the ApV upon its formation and remain associated throughout infection. Endogenous Rab14 localizes to the ApV. Tetracycline treatment concomitantly promotes loss of recycling endosome‐associated GFP‐Rabs and acquisition of GFP‐Rab5, GFP‐Rab7, and the lysosomal marker, LAMP‐1. Wild‐type and GTPase‐ deficient versions, but not GDP‐restricted versions of GFP‐Rab1, GFP‐Rab4A and GFP‐Rab11A, localize to the ApV. Strikingly, GFP‐Rab10 recruitment to the ApV is guanine nucleotide‐independent. These data establish that A. phagocytophilum selectively recruits Rab GTPases that are primarily associated with recycling endosomes to facilitate its intracellular survival and implicate bacterial proteins in regulating Rab10 membrane cycling on the ApV.     

Toll‐like receptor signalling cross‐activates the autophagic pathway to restrict Salmonella Typhimurium growth in macrophages

It has been long recognised that activation of toll‐like receptors (TLRs) induces autophagy to restrict intracellular bacterial growth. However, the mechanisms of TLR‐induced autophagy are incompletely understood. Salmonella Typhimurium is an intracellular pathogen that causes food poisoning and gastroenteritis in humans. Whether TLR activation contributes to S. Typhimurium‐induced autophagy has not been investigated. Here, we report that S. Typhimurium and TLRs shared a common pathway to induce autophagy in macrophages. We first showed that S. Typhimurium‐induced autophagy in a RAW264.7 murine macrophage cell line was mediated by the AMP‐activated protein kinase (AMPK) through activation of the TGF‐β‐activated kinase (TAK1), a kinase activated by multiple TLRs. AMPK activation led to increased phosphorylation of Unc‐51‐like autophagy activating kinase (ULK1) at S317 and S555. ULK1 phosphorylation at these two sites in S. Typhimurium‐infected macrophages overrode the inhibitory effect of mTOR on ULK1 activity due to mTOR‐mediated ULK1 phosphorylation at S757. Lipopolysaccharide (LPS), flagellin, and CpG oligodeoxynucleotide, which activate TLR4, TLR5, and TLR9, respectively, increased TAK1 and AMPK phosphorylation and induced autophagy in RAW264.7 cells and in bone marrow‐derived macrophages. However, LPS was unable to induce TAK1 and AMPK phosphorylation and autophagy in TLR4‐deficient macrophages. TAK1 and AMPK‐specific inhibitors blocked S. Typhimurium‐induced autophagy and xenophagy and increased the bacterial growth in RAW264.7 cells. These observations collectively suggest that activation of the TAK1–AMPK axis through TLRs is essential for S. Typhimurium‐induced autophagy and that TLR signalling cross‐activates the autophagic pathway to clear intracellular bacteria.     

A proof‐of‐concept study in engineering synthetic protein for selective recognition of substrate‐free polyubiquitin

Similar to substrate‐conjugated polyubiquitin, unanchored polyubiquitin chains are emerging as important regulators for diverse biological processes. The affinity purification of unanchored polyubiquitin from various organisms has been reported, however, tools able to distinguish unanchored polyubiquitin chains with different isopeptide linkages have not yet been described. Toward the goal of selectively identifying and purifying unanchored polyubiquitin chains linked through different Lysines, Scott et al. developed a novel strategy in their study [Proteomics 2016, 16, 1961–1969]. They designed a linker‐optimized ubiquitin‐binding domain hybrid (t‐UBD) containing two UBDs, a ZnFCUBP domain, and a linkage‐selective UBA domain, to specifically recognize unanchored Lys48‐linked polyubiquitin chains. Subsequently, a series of assays has proved the feasibility of this novel strategy for the purification of endogenous substrate‐free Lys48‐linked polyubiquitin chains from mammalian cell extracts. Their research not only provides a tool for purifying unanchored polyubiquitin with different isopeptide linkages, but also paves the way for generating reagents to study the function of unanchored polyubiquitin chains of different linkages in the future. The design of UBD hybrids for defined unanchored polyubiquitin (Lys48‐polyubiquitin) in this study also set an excellent example for future methodology studies regarding monitoring in vivo dynamic changes in the patterns of ubiquitination.