Hydrophilic Subunits Research Articles

Amphiphilic Polymer Electrolyte Blocking Lattice Oxygen Evolution from High‐Voltage Nickel‐rich Cathodes for Ultra‐Thermal Stabile Batteries

AbstractNi‐rich cathodes have been intensively adopted in Li‐ion batteries to pursuit high energy density, which still suffering irreversible degradation at high voltage. Some unstable lattice O2− species in Ni‐rich cathodes would be oxidized to singlet oxygen 1O2 and released at high volt, which lead to irreversible phase transfer from the layered rhombohedral (R) phase to a spinel‐like (S) phase. To overcome the issue, the amphiphilic copolymers (UMA‐Fx) electrolyte were prepared by linking hydrophobic C−F side chains with hydrophilic subunits, which could self‐assemble on Ni‐rich cathode surface and convert to stable cathode–electrolyte interphase layer. Thereafter, the oxygen releasing of polymer coated cathode was obviously depressed and substituted by the Co oxidation (Co3+→Co4+) at high volt (>4.2 V), which could suppressed irreversible phase transfer and improve cycling stability. Moreover, the amphiphilic polymer electrolyte was also stable with Li anode and had high ion conductivity. Therefore, the NCM811//UMA‐F6//Li pouch cell exhibited outstanding energy density (362.97 Wh/kg) and durability (cycled 200 times at 4.7 V), which could be stalely cycled even at 120°C without short circuits or explosions.

The PsbJ protein is required for photosystem II activity in centers lacking the PsbO and PsbV lumenal subunits.

Photosystem II (PS II) of oxygenic photosynthesis is found in the thylakoid membranes of plastids and cyanobacteria. The mature PS II complex comprises a central core of four membrane proteins that bind the majority of the redox-active cofactors. In cyanobacteria the central core is surrounded by 13 low-molecular-weight (LMW) subunits which each consist of one or two transmembrane helices. Three additional hydrophilic subunits known as PsbO, PsbU and PsbV are found associated with hydrophilic loops belonging to the core proteins protruding into the thylakoid lumen. During biogenesis the majority of the LMW subunits are known to initially associate with individual pre-assembly complexes consisting of one or more of the core proteins; however, the point at which the PsbJ LMW subunit binds to PS II is not known. The majority of models for PS II biogenesis propose that the three extrinsic proteins and PsbJ bind in the final stages of PS II assembly. We have investigated the impact of creating the double mutants ∆PsbJ:∆PsbO, ∆PsbJ:∆PsbU and ∆PsbJ:∆PsbV to investigate potential cooperation between these subunits in the final stages of biogenesis. Our results indicate that PsbJ can bind to PS II in the absence of any one of the extrinsic proteins. However, unlike their respective single mutants, the ∆PsbJ:∆PsbO and ∆PsbJ:∆PsbV strains were not photoautotrophic and were unable to support oxygen evolution suggesting a functional oxygen-evolving complex could not assemble in these strains. In contrast, the PS II centers formed in the ∆PsbJ:∆PsbU strain were capable of photoautotrophic growth and could support oxygen evolution when whole-chain electron transport was supported by the addition of bicarbonate.

The human coronavirus HCoV-229E S-protein structure and receptor binding.

The coronavirus S-protein mediates receptor binding and fusion of the viral and host cell membranes. In HCoV-229E, its receptor binding domain (RBD) shows extensive sequence variation but how S-protein function is maintained is not understood. Reported are the X-ray crystal structures of Class III-V RBDs in complex with human aminopeptidase N (hAPN), as well as the electron cryomicroscopy structure of the 229E S-protein. The structures show that common core interactions define the specificity for hAPN and that the peripheral RBD sequence variation is accommodated by loop plasticity. The results provide insight into immune evasion and the cross-species transmission of 229E and related coronaviruses. We also find that the 229E S-protein can expose a portion of its helical core to solvent. This is undoubtedly facilitated by hydrophilic subunit interfaces that we show are conserved among coronaviruses. These interfaces likely play a role in the S-protein conformational changes associated with membrane fusion.

Structural insights into the electron/proton transfer pathways in the quinol:fumarate reductase from Desulfovibrio gigas

The membrane-embedded quinol:fumarate reductase (QFR) in anaerobic bacteria catalyzes the reduction of fumarate to succinate by quinol in the anaerobic respiratory chain. The electron/proton-transfer pathways in QFRs remain controversial. Here we report the crystal structure of QFR from the anaerobic sulphate-reducing bacterium Desulfovibrio gigas (D. gigas) at 3.6 Å resolution. The structure of the D. gigas QFR is a homo-dimer, each protomer comprising two hydrophilic subunits, A and B, and one transmembrane subunit C, together with six redox cofactors including two b-hemes. One menaquinone molecule is bound near heme bL in the hydrophobic subunit C. This location of the menaquinone-binding site differs from the menaquinol-binding cavity proposed previously for QFR from Wolinella succinogenes. The observed bound menaquinone might serve as an additional redox cofactor to mediate the proton-coupled electron transport across the membrane. Armed with these structural insights, we propose electron/proton-transfer pathways in the quinol reduction of fumarate to succinate in the D. gigas QFR.

NdhV subunit regulates the activity of type-1 NAD(P)H dehydrogenase under high light conditions in cyanobacterium Synechocystis sp. PCC 6803.

The cyanobacterial NAD(P)H dehydrogenase (NDH-1) complexes play crucial roles in variety of bioenergetic reactions. However, the regulative mechanism of NDH-1 under stressed conditions is still unclear. In this study, we detected that the NDH-1 activity is partially impaired, but the accumulation of NDH-1 complexes was little affected in the NdhV deleted mutant (ΔndhV) at low light in cyanobacterium Synechocystis sp. PCC 6803. ΔndhV grew normally at low light but slowly at high light under inorganic carbon limitation conditions (low pH or low CO2), meanwhile the activity of CO2 uptake was evidently lowered than wild type even at pH 8.0. The accumulation of NdhV in thylakoids strictly relies on the presence of the hydrophilic subcomplex of NDH-1. Furthermore, NdhV was co-located with hydrophilic subunits of NDH-1 loosely associated with the NDH-1L, NDH-1MS′ and NDH-1M complexes. The level of the NdhV was significantly increased at high light and deletion of NdhV suppressed the up-regulation of NDH-1 activity, causing the lowered the photosynthetic oxygen evolution at pH 6.5 and high light. These data indicate that NdhV is an intrinsic subunit of hydrophilic subcomplex of NDH-1, required for efficient operation of cyclic electron transport around photosystem I and CO2 uptake at high lights.

Functional Characterization of the Subunits N, H, J, and O of the NAD(P)H Dehydrogenase Complexes in Synechocystis sp. Strain PCC 6803.

The cyanobacterial NAD(P)H dehydrogenase (NDH-1) complexes play crucial roles in variety of bioenergetic reactions such as respiration, CO2 uptake, and cyclic electron transport around PSI. Recently, substantial progress has been made in identifying the composition of subunits of NDH-1 complexes. However, the localization and the physiological roles of several subunits in cyanobacteria are not fully understood. Here, by constructing fully segregated ndhN, ndhO, ndhH, and ndhJ null mutants in Synechocystis sp. strain PCC 6803, we found that deletion of ndhN, ndhH, or ndhJ but not ndhO severely impaired the accumulation of the hydrophilic subunits of the NDH-1 in the thylakoid membrane, resulting in disassembly of NDH-1MS, NDH-1MS', as well as NDH-1L, finally causing the severe growth suppression phenotype. In contrast, deletion of NdhO affected the growth at pH 6.5 in air. In the cytoplasm, either NdhH or NdhJ deleted mutant, but neither NdhN nor NdhO deleted mutant, failed to accumulate the NDH-1 assembly intermediate consisting of NdhH, NdhJ, NdhK, and NdhM. Based on these results, we suggest that NdhN, NdhH, and NdhJ are essential for the stability and the activities of NDH-1 complexes, while NdhO for NDH-1 functions under the condition of inorganic carbon limitation in Synechocystis sp. strain PCC 6803. We discuss the roles of these subunits and propose a new NDH-1 model.

NdhM Subunit Is Required for the Stability and the Function of NAD(P)H Dehydrogenase Complexes Involved in CO2 Uptake in Synechocystis sp. Strain PCC 6803

The cyanobacterial type I NAD(P)H dehydrogenase (NDH-1) complexes play a crucial role in a variety of bioenergetic reactions such as respiration, CO2 uptake, and cyclic electron transport around photosystem I. Two types of NDH-1 complexes, NDH-1MS and NDH-1MS′, are involved in the CO2 uptake system. However, the composition and function of the complexes still remain largely unknown. Here, we found that deletion of ndhM caused inactivation of NDH-1-dependent cyclic electron transport around photosystem I and abolishment of CO2 uptake, resulting in a lethal phenotype under air CO2 condition. The mutation of NdhM abolished the accumulation of the hydrophilic subunits of the NDH-1, such as NdhH, NdhI, NdhJ, and NdhK, in the thylakoid membrane, resulting in disassembly of NDH-1MS and NDH-1MS′ as well as NDH-1L. In contrast, the accumulation of the hydrophobic subunits was not affected in the absence of NdhM. In the cytoplasm, the NDH-1 subcomplex assembly intermediates including NdhH and NdhK were seriously affected in the ΔndhM mutant but not in the NdhI-deleted mutant ΔndhI. In vitro protein interaction analysis demonstrated that NdhM interacts with NdhK, NdhH, NdhI, and NdhJ but not with other hydrophilic subunits of the NDH-1 complex. These results suggest that NdhM localizes in the hydrophilic subcomplex of NDH-1 complexes as a core subunit and is essential for the function of NDH-1MS and NDH-1MS′ involved in CO2 uptake in Synechocystis sp. strain PCC 6803.

ChemInform Abstract: Rational Strategies for the Selective Functionalization of Calixarenes

AbstractReview: [35 refs.

Rational Strategies for the Selective Functionalization of Calixarenes

AbstractCalixarenes are widely used as molecular platforms in supramolecular chemistry. Their efficient modification is key for appending functional moieties such as binding, sensing, chiral, or hydrophilic subunits. Due to the presence of multiple identical functional groups, selective functionalization of such macrocyclic compounds is highly challenging. Indeed, the control of the chemo‐, regio‐, stereo‐ as well as iteroselectivity is required. This review describes rational methods leading to a high degree of regio‐ and/or iteroselectivity and classifies them into specific strategies. Many of these strategies are conceptually very general and hopefully will be a source of inspiration for developing selective methods for other macrocyclic platforms.

Expression of a nuclear-encoded psbH gene complements the plastidic RNA processing defect in the PSII mutant hcf107 in Arabidopsis thaliana.

The helical-repeat RNA-binding protein HCF107 is required for processing, stabilization and translation of plastid-encoded psbH mRNA. The psbH gene encodes a small, hydrophilic subunit of the PSII complex and is part of the plastidic psbB-psbT-psbH-petB-petD transcription unit. In Arabidopsis hcf107 mutants, only trace amounts of PSII proteins can be detected. Beside drastically reduced synthesis of PsbH, the synthesis of CP47 was also reduced in these mutants, although the corresponding psbB transcripts accumulate to wild type levels. This situation raises the question, whether the reduction of CP47 is a direct consequence of the mutation, based on targeting of HCF107 to the psbB mRNA, or a secondary affect due to the absent PsbH. To clarify this issue we introduced a chimeric psbH construct comprising a sequence encoding a chloroplast transit peptide into the hcf107-2 background. We found that the nucleus-localized psbH was able to complement the mutant defect resulting in photoautotrophic plants. The PSII proteins CP47 and D1 accumulated to barely half of the wild type level. Further experiments showed that cytosolically synthesized PsbH was imported into chloroplasts and assembled into PSII complexes. Using this approach, we showed that the tetratricopeptide repeat protein HCF107 of Arabidopsis is only responsible for expression of PsbH and not for synthesis of CP47. In addition the data suggest the necessity of the small, one-helix membrane spanning protein PsbH for the accumulation of CP47 in higher plants.

Self-assembly of flagellin on Au(111) surfaces

The adsorption of flagellin monomers from Pseudomonas fluorescens on Au(111) has been studied by Atomic Force Microscopy (AFM), Scanning Tunneling Microscopy (STM), X-ray Photoelectron Spectroscopy (XPS), Surface Plasmon Resonance (SPR), and electrochemical techniques. Results show that flagellin monomers spontaneously self-assemble forming a monolayer thick protein film bounded to the Au surface by the more hydrophobic subunit and exposed to the environment the hydrophilic subunit. The films are conductive and allow allocation of electrochemically active cytochrome C. The self-assembled films could be used as biological platforms to build 3D complex molecular structures on planar metal surfaces and to functionalize metal nanoparticles.

Subunit δ Is the Key Player for Assembly of the H+-translocating Unit of Escherichia coli FOF1 ATP Synthase

The ATP synthase (F(O)F1) of Escherichia coli couples the translocation of protons across the cytoplasmic membrane to the synthesis or hydrolysis of ATP. This nanomotor is composed of the rotor c10γε and the stator ab2α3β3δ. To study the assembly of this multimeric enzyme complex consisting of membrane-integral as well as peripheral hydrophilic subunits, we combined nearest neighbor analyses by intermolecular disulfide bond formation or purification of partially assembled F(O)F1 complexes by affinity chromatography with the use of mutants synthesizing different sets of F(O)F1 subunits. Together with a time-delayed in vivo assembly system, the results demonstrate that F(O)F1 is assembled in a modular way via subcomplexes, thereby preventing the formation of a functional H(+)-translocating unit as intermediate product. Surprisingly, during the biogenesis of F(O)F1, F1 subunit δ is the key player in generating stable F(O). Subunit δ serves as clamp between ab2 and c10α3β3γε and guarantees that the open H(+) channel is concomitantly assembled within coupled F(O)F1 to maintain the low membrane proton permeability essential for viability, a general prerequisite for the assembly of multimeric H(+)-translocating enzymes.

Unravelling the folding and stability of an ABC (ATP-binding cassette) transporter

Prokaryotic importers from the large family of ABC (ATP-binding cassette) transporters comprise four separate subunits: two membrane-embedded and two cytoplasmic ATP-binding subunits. This modular construction makes them ideal candidates for studies of the intersubunit interactions of membrane protein complexes that contain both hydrophobic and hydrophilic subunits. In the present paper, we focus on the vitamin B12 importer of Escherichia coli, BtuCD, that contains two transmembrane BtuC subunits and two ATP-binding BtuD subunits. We have studied the factors that induce subunit dissociation and unfolding in vitro. The BtuCD complex remains intact in alcohol and mild detergents, but urea or SDS separate the BtuC and BtuD subunits, with 6M urea causing 80% of BtuD to be removed from BtuCD. ATP is found to stabilize the complex as a result of its binding to the BtuD subunits. In the absence of ATP, low concentrations of urea (0.5-3M) also induce some unfolding, with approximately 14% reduction in helicity in 3M urea, whereas, in the presence of ATP, no changes are observed. Disassembly at the BtuD-BtuD dimeric interface in BtuCD can be achieved with smaller concentrations of urea (0.5-3M) than that required to cause disassembly at the BtuC-BtuD transmission interface (3-8M), suggesting a stronger interaction of the latter. The results also suggest that unfolding and disassociation of subunits appear to be coupled processes. Our work provides insights into the subunit interactions of an ABC transporter and lays the foundation for studies of the reassembly of BtuCD.

In Vitro Folding and Assembly of the Escherichia coli ATP-binding Cassette Transporter, BtuCD

Studies on membrane protein folding have focused on monomeric α-helical proteins and a major challenge is to extend this work to larger oligomeric membrane proteins. Here, we study the Escherichia coli (E. coli) ATP-binding cassette (ABC) transporter that imports vitamin B(12) (the BtuCD protein) and use it as a model system for investigating the folding and assembly of a tetrameric membrane protein complex. Our work takes advantage of the modular organization of BtuCD, which consists of two transmembrane protein subunits, BtuC, and two cytoplasmically located nucleotide-binding protein subunits, BtuD. We show that the BtuCD transporter can be re-assembled from both prefolded and partly unfolded, urea denatured BtuC and BtuD subunits. The in vitro re-assembly leads to a BtuCD complex with the correct, native, BtuC and BtuD subunit stoichiometry. The highest rates of ATP hydrolysis were achieved for BtuCD re-assembled from partly unfolded subunits. This supports the idea of cooperative folding and assembly of the constituent protein subunits of the BtuCD transporter. BtuCD folding also provides an opportunity to investigate how a protein that contains both membrane-bound and aqueous subunits coordinates the folding requirements of the hydrophobic and hydrophilic subunits.

Pivotal Roles of Three Conserved Carboxyl Residues of the NuoC (30k) Segment in the Structural Integrity of Proton-Translocating NADH-Quinone Oxidoreductase from Escherichia coli

The prokaryotic proton-translocating NADH-quinone oxidoreductase (NDH-1) is an L-shaped membrane-bound enzyme that contains 14 subunits (NuoA-NuoN or Nqo1-Nqo14). All subunits have their counterparts in the eukaryotic enzyme (complex I). NDH-1 consists of two domains: the peripheral arm (NuoB, -C, -D, -E, -F, -G, and -I) and the membrane arm (NuoA, -H, -J, -K, -L, -M, and -N). In Escherichia coli NDH-1, the hydrophilic subunits NuoC/Nqo5/30k and NuoD/Nqo4/49k are fused together in a single polypeptide as the NuoCD subunit. The NuoCD subunit is the only subunit that does not bear a cofactor in the peripheral arm. While some roles for inhibitor and quinone association have been reported for the NuoD segment, structural and functional roles of the NuoC segment remain mostly elusive. In this work, 14 highly conserved residues of the NuoC segment were mutated and 21 mutants were constructed using the chromosomal gene manipulation technique. From the enzymatic assays and immunochemical and blue-native gel analyses, it was found that residues Glu-138, Glu-140, and Asp-143 that are thought to be in the third α-helix are absolutely required for the energy-transducing NDH-1 activities and the assembly of the whole enzyme. Together with available information for the hydrophobic subunits, we propose that Glu-138, Glu-140, and Asp-143 of the NuoC segment may have a pivotal role in the structural stability of NDH-1.

The Subunit Composition of Mitochondrial NADH:Ubiquinone Oxidoreductase (Complex I) From Pichia pastoris

Respiratory complex I (NADH:quinone oxidoreductase) is an entry point to the electron transport chain in the mitochondria of many eukaryotes. It is a large, multisubunit enzyme with a hydrophilic domain in the matrix and a hydrophobic domain in the mitochondrial inner membrane. Here we present a comprehensive analysis of the protein composition and post-translational modifications of complex I from Pichia pastoris, using a combination of proteomic and bioinformatic approaches. Forty-one subunits were identified in P. pastoris complex I, comprising the 14 core (conserved) subunits and 27 supernumerary subunits; seven of the core subunits are mitochondrial encoded. Three of the supernumerary subunits (named NUSM, NUTM, and NUUM) have not been observed previously in any species of complex I. However, homologues to all three of them are present in either Yarrowia lipolytica or Pichia angusta complex I. P. pastoris complex I has 39 subunits in common with Y. lipolytica complex I, 37 in common with N. crassa complex I, and 35 in common with the bovine enzyme. The mitochondrial encoded subunits (translated by the mold mitochondrial genetic code) retain their N-α-formyl methionine residues. At least eight subunits are N-α-acetylated, but the N-terminal modifications of the nuclear encoded subunits are not well-conserved. A combination of two methods of protein separation (SDS-PAGE and HPLC) and three different mass spectrometry techniques (peptide mass fingerprinting, tandem MS and molecular mass measurements) were required to define the protein complement of P. pastoris complex I. This requirement highlights the need for inclusive and comprehensive strategies for the characterization of challenging membrane-bound protein complexes containing both hydrophilic and hydrophobic components.

Production, characterization and determination of the real catalytic properties of the putative ‘succinate dehydrogenase’ from Wolinella succinogenes

Both the genomes of the epsilonproteobacteria Wolinella succinogenes and Campylobacter jejuni contain operons (sdhABE) that encode for so far uncharacterized enzyme complexes annotated as ‘non-classical’ succinate:quinone reductases (SQRs). However, the role of such an enzyme ostensibly involved in aerobic respiration in an anaerobic organism such as W. succinogenes has hitherto been unknown. We have established the first genetic system for the manipulation and production of a member of the non-classical succinate:quinone oxidoreductase family. Biochemical characterization of the W. succinogenes enzyme reveals that the putative SQR is in fact a novel methylmenaquinol:fumarate reductase (MFR) with no detectable succinate oxidation activity, clearly indicative of its involvement in anaerobic metabolism. We demonstrate that the hydrophilic subunits of the MFR complex are, in contrast to all other previously characterized members of the superfamily, exported into the periplasm via the twin-arginine translocation (tat)-pathway. Furthermore we show that a single amino acid exchange (Ala86→His) in the flavoprotein of that enzyme complex is the only additional requirement for the covalent binding of the otherwise non-covalently bound FAD. Our results provide an explanation for the previously published puzzling observation that the C. jejuni sdhABE operon is upregulated in an oxygen-limited environment as compared with microaerophilic laboratory conditions.

Three novel subunits of Arabidopsis chloroplastic NAD(P)H dehydrogenase identified by bioinformatic and reverse genetic approaches

Chloroplastic NAD(P)H dehydrogenase (NDH) plays a role in cyclic electron flow around photosystem I to produce ATP, especially in adaptation to environmental changes. Although the NDH complex contains 11 subunits that are homologous to NADH:ubiquinone oxidoreductase (complex I; EC 1.6.5.3), recent genetic and biological studies have indicated that NDH also comprises unique subunits. We describe here an in silico approach based on co-expression analysis and phylogenetic profiling that was used to identify 65 genes as potential candidates for NDH subunits. Characterization of 21 Arabidopsis T-DNA insertion mutants among these ndh gene candidates indicated that three novel ndf (NDH-dependent cyclic electron flow) mutants (ndf1, ndf2 and ndf4) had impaired NDH activity as determined by measurement of chlorophyll fluorescence. The amount of NdhH subunit was greatly decreased in these mutants, suggesting that the loss of NDH activity was caused by a defect in accumulation of the NDH complex. In addition, NDF1, NDF2 and NDF4 proteins co-migrated with the NdhH subunit, as shown by blue native electrophoresis. These results strongly suggest that NDF proteins are novel subunits of the NDH complex. Further analysis revealed that the NDF1 and NDF2 proteins were unstable in the mutants lacking hydrophobic subunits of the NDH complex, but were stable in mutants lacking the hydrophilic subunits, suggesting that NDF1 and NDF2 interact with a hydrophobic sub-complex. NDF4 protein was predicted to possess a redox-active iron-sulfur cluster domain that may be involved in the electron transfer.

Novel Nuclear-encoded Subunits of the Chloroplast NAD(P)H Dehydrogenase Complex

The NAD(P)H dehydrogenase (NDH) complex functions in photosystem I cyclic electron transfer in higher plant chloroplasts and is crucial for plant responses to environmental stress. Chloroplast NDH complex is a close relative to cyanobacterial NDH-1L complex, and all fifteen subunits so far identified in NDH-1L have homologs in the chloroplast NDH complex. Here we report on the identification of two nuclear-encoded proteins NDH48 and NDH45 in higher plant chloroplasts and show their intimate association with the NDH complex. These two membrane proteins are shown to interact with each other and with the NDH complex enriched in stroma thylakoids. Moreover, the deficiency of either the NDH45 protein or the NDH48 protein in respective mutant plants leads to severe defects in both the accumulation and the function of the NDH complex. The NDH48 and NDH45 proteins are not components of the hydrophilic connecting domain of the NDH complex but are strongly attached to the hydrophobic membrane domain. We conclude that NDH48 and NDH45 are novel nuclear-encoded subunits of the chloroplast NDH complex and crucial both for the stable structure and function of the NDH complex.

HPLC-based quantification of haemagglutinin in the production of egg- and MDCK cell-derived influenza virus seasonal and pandemic vaccines

The haemagglutinin (HA) content is an important specification of influenza vaccines. Recently, a reversed-phase high performance liquid chromatography (RP-HPLC) method for quantification of HA in PER.C6® cell culture-based whole virus vaccines has been reported, having a high sensitivity, precision, broad range, and high sample throughput [Kapteyn JC, Drissi Saidi M, Dijkstra R, Kars C, Tjon CMS-K, Weverling GJ et al. Haemagglutinin quantification and identification of influenza A&B strains propagated in PER.C6® cells: a novel RP-HPLC method. Vaccine 2006;24:3137–44]. This RP-HPLC assay is based on measuring the peak area of HA1, the hydrophilic subunit of HA, which turned out to be proportional to the amount of HA analyzed. Here, we present data demonstrating that this RP-HPLC method is also highly suitable for HA quantification of active and BPL- or formaldehyde-inactivated egg-based and MDCK cell-based whole virus samples, including egg allantoic harvest, and in final (monovalent) subunit vaccines, including those for pandemic H5N1 strains and for virosomal vaccines. In addition, the RP-HPLC assay was demonstrated to be a very powerful tool in the early stages of seasonal influenza vaccine production, when homologous serial radial immunodiffusion (SRID) reagents are not yet available, enabling fast and reliable viral growth studies in eggs in order to select the best growing virus strains or reassortants for the production of the seasonal trivalent influenza vaccine. Because of its high sensitivity, the RP-HPLC assay has shown its enormous value in supporting small scale MDCK-based (H5N1) influenza virus production models. Finally, the observed differences between HA1 molecules from various HA subtypes in UV absorbance, FLD response, and in the actual retention times in RP-HPLC are discussed in relation to the primary structure of the HA1 molecules studied.