NanoPad: An integrated platform for bacterial production of camel nanobodies aimed at detecting environmental biomarkers

Application of Single-Domain Antibodies ("Nanobodies") to Laboratory Diagnosis

Antibodies have proven to be central in the development of diagnostic methods over decades, moving from polyclonal antibodies to the milestone development of monoclonal antibodies. Although monoclonal antibodies play a valuable role in diagnosis, their production is technically demanding and can be expensive. The large size of monoclonal antibodies (150 kDa) makes their re-engineering using recombinant methods a challenge. Single-domain antibodies, such as “nanobodies,” are a relatively new class of diagnostic probes that originated serendipitously during the assay of camel serum. The immune system of the camelid family (camels, llamas, and alpacas) has evolved uniquely to produce heavy-chain antibodies that contain a single monomeric variable antibody domain in a smaller functional unit of 12–15 kDa. Interestingly, the same biological phenomenon is observed in sharks. Since a single-domain antibody molecule is smaller than a conventional mammalian antibody, recombinant engineering and protein expression in vitro using bacterial production systems are much simpler. The entire gene encoding such an antibody can be cloned and expressed in vitro. Single-domain antibodies are very stable and heat-resistant, and hence do not require cold storage, especially when incorporated into a diagnostic kit. Their simple genetic structure allows easy re-engineering of the protein to introduce new antigen-binding characteristics or attach labels. Here, we review the applications of single-domain antibodies in laboratory diagnosis and discuss the future potential in this area.

Engineering Tropism of Pseudomonas putida toward Target Surfaces through Ectopic Display of Recombinant Nanobodies

Gram-negative bacteria are endowed with complex outer membrane (OM) structures that allow them to both interact with other organisms and attach to different physical structures. However, the design of reliable bacterial coatings of solid surfaces is still a considerable challenge. In this work, we report that ectopic expression of a fibrinogen-specific nanobody on the envelope of Pseudomonas putida cells enables controllable formation of a bacterial monolayer strongly bound to an antigen-coated support. To this end, either the wild type or a surface-naked derivative of P. putida was engineered to express a hybrid between the β-barrel of an intimin-type autotransporter inserted in the outer membrane and a nanobody (VHH) moiety that targets fibrinogen as its cognate interaction partner. The functionality of the thereby presented VHH and the strength of the resulting cell attachment to a solid surface covered with the cognate antigen were tested and parametrized with Quartz Crystal Microbalance technology. The results not only demonstrated the value of using bacteria with reduced OM complexity for efficient display of artificial adhesins, but also the potential of this approach to engineer specific bacterial coverings of predetermined target surfaces.

Synthetic consortia of nanobody-coupled and formatted bacteria for prophylaxis and therapy interventions targeting microbiome dysbiosis-associated diseases and co-morbidities

Designed nanobody-linked synthetic consortia for microbiota dysbiosis therapies. A. Nanobodies (Nb) are selected for specific antigens on target bacteria destined for a synthetic therapy consortium that may consist of two (B) or multiple (C) members. For the treatment of dysbiosis co-morbidities requiring two functionally distinct consortia, these may be linked through a common member to generate a single bi-functional microbiota therapy (D).

Molecular analysis of some camel cytochrome P450 enzymes reveals lower evolution and drug-binding properties

Camels bear unique genotypes and phenotypes for adaptation of their harsh environment. They have unique visual systems, sniffing, water metabolism, and heat-control mechanisms that are different from other creatures. The recent announcement for the complete sequence of camel genome will allow for the discovery of many secrets of camel life. In this context, the genetic bases of camel drug-metabolizing enzymes are still unknown. Furthermore, the genomic content of camel that rendered it highly susceptible to some drugs (as monensin and salinomycin) and became easily intoxicated needs to be investigated. The objectives of this work are the annotation of camel genome and retrieval of camel for cytochrome P450 (CYP) 1A1, 2C, and 3A enzymes. This is followed by comprehensive phylogenetic, evolution, molecular modeling, and docking studies. In comparison with the human enzymes, camel CYPs showed lower evolution rate, especially CYP1A1. Furthermore, the binding of monensin, salinomycin, alfa-naphthoflavone, felodepine, and ritonavir was weaker in camel enzymes. Interestingly, rerank score indicated instable binding of monensin and salinomycin with camel CYP1A1 as well as salinomycin with camel CYP2C. The results of this work suggest that camels are more susceptible to toxicity with compounds undergoing metabolic oxidation. This conclusion was based on lower evolution rate and lower binding potency of camels compared with the human enzymes.

Nanobody-based products as research and diagnostic tools

Since the serendipitous discovery 20 years ago of bona fide camelid heavy-chain antibodies, their single-domain antigen-binding fragments, known as VHHs or nanobodies, have received a progressively growing interest. As a result of the beneficial properties of these stable recombinant entities, they are currently highly valued proteins for multiple applications, including fundamental research, diagnostics, and therapeutics. Today, with the original patents expiring, even more academic and industrial groups are expected to explore innovative VHH applications. Here, we provide a thorough overview of novel implementations of VHHs as research and diagnostic tools, and of the recently evaluated production platforms for several VHHs and VHH-derived antibody formats.