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Heptose

A heptose is a containing seven carbon atoms in its straight-chain form, making it a polyhydroxy (aldoheptose) or (ketoheptose) with the general C₇H₁₄O₇. Unlike more prevalent hexoses such as glucose, heptoses are relatively rare in and typically exist in cyclic forms, including or rings, though septanose (seven-membered) configurations occur in specific contexts. Heptoses play diverse roles in biology, primarily as intermediates in metabolic pathways and structural components in microbial systems. The ketoheptose sedoheptulose, often as its 7-phosphate derivative, is a key intermediate in the non-oxidative phase of the , facilitating the interconversion of sugars for synthesis and redox balance, and in the Calvin-Benson-Bassham cycle of , where it aids carbon fixation in . Another ketoheptose, mannoheptulose, is found in fruits like avocados and figs, where it may influence insulin secretion and glucose metabolism. In microorganisms, aldoheptoses such as L-glycero-D-manno-heptose are essential constituents of the inner core in lipopolysaccharides (LPS) of , including Escherichia coli and Helicobacter pylori, contributing to outer membrane integrity, endotoxic activity, and evasion of host immune responses via pathways like activation. These sugars' , often from sedoheptulose-7-phosphate via isomerases like GmhA, underscores their importance in antibiotic targets and vaccine development against bacterial pathogens.

Definition and Structure

Definition

A heptose is a class of monosaccharides characterized by containing exactly seven carbon atoms in their linear, open-chain form. These sugars are distinguished from other saccharides, such as hexoses with six carbon atoms, primarily by this carbon count, which influences their structural complexity and biochemical roles. The general molecular formula for the open-chain structure of heptoses is C_7H_{14}O_7, which applies to both aldoheptoses (with an group) and ketoheptoses (with a group)./05%3A_Carbohydrates/5.02%3A_General_class_names_and_Common_names_monosaccharides) The and of heptoses emerged in the late as part of broader efforts to systematize chemistry, led by Fischer's pioneering syntheses and structural elucidations of series.

Molecular Structure

Heptoses exist primarily in linear and cyclic forms, with the linear chain consisting of seven carbon atoms bearing multiple hydroxyl groups and a carbonyl functionality. In aldoheptoses, the carbonyl is an group at C1, followed by five chiral carbons (C2–C6) each attached to a hydroxyl group, and terminating in a CH₂OH group at C7. Ketoheptoses feature a group at C2, with CH₂OH groups at C1 and C7, and four chiral carbons (C3–C6) each bearing a hydroxyl group. In , heptoses equilibrate to cyclic structures, where a hydroxyl group (typically from or ) reacts intramolecularly with the carbonyl to form a ring and generate a new chiral center at the anomeric carbon (former carbonyl carbon). The predominant cyclic forms are the (five-membered ring involving C1–C4 or equivalent for ketoses) and (six-membered ring involving C1–C5 or C2–C6), with generally favored due to its greater stability. Fischer projections represent the linear forms of heptoses with the carbon chain aligned vertically, the carbonyl at the top, and horizontal lines indicating bonds to hydroxyl and hydrogen groups projecting forward. The D- and L-series designation for heptoses is based on the at , the highest-numbered chiral carbon: a hydroxyl group on the right defines the D-series, while on the left defines the L-series. The five chiral centers in aldoheptoses yield $2^5 = 32 possible stereoisomers in the linear form, comprising 16 D-isomers and 16 L-isomers. Ketoheptoses, with four chiral centers, possess $2^4 = 16 stereoisomers.

Classification

Aldoheptoses

Aldoheptoses constitute the subclass of heptoses featuring an functional group at the C1 position in their open-chain form, with the general molecular C₇H₁₄O₇. In this linear , carbons 2 through 6 serve as chiral centers due to the presence of hydroxyl groups, while C7 terminates in a (-CH₂OH); upon cyclization, the anomeric carbon at C1 introduces an additional chiral center, resulting in six chiral carbons overall. The of aldoheptoses arises from the five chiral centers in the open-chain form, yielding a maximum of 2⁵ = 32 stereoisomers, evenly divided into 16 D-enantiomers and 16 L-enantiomers, with the D/L designation determined by the at the penultimate carbon (C6). These configurations are conventionally depicted in projections, where the carbon chain is vertically oriented with the at the top, and stereodescriptors such as "glycero" and "" specify the relative arrangements at specific chiral centers, often using a binary naming system to denote the two highest-numbered chiral carbons. Optical activity in aldoheptoses stems from this , with specific rotations varying by stereoisomer due to differences in asymmetric induction. The Kiliani-Fischer synthesis provides a key method for generating aldoheptoses by extending the carbon chain of aldohexoses through formation followed by and , producing two epimeric aldoheptoses differing at the new C2 chiral center; this approach has been instrumental in elucidating stereochemical relationships among higher aldoses. Representative aldoheptoses include D-glycero-D-gulo-heptose, which features the (2R,3R,4S,5R,6R) in its open-chain form. Another notable example is D-glycero-D-altro-heptose, characterized by its distinct stereochemistry at multiple chiral centers and often synthesized for studies of bacterial . A biologically significant example is L-glycero-D-manno-heptose, found in bacterial lipopolysaccharides. Compared to more prevalent hexoses, aldoheptoses are rare in nature, occurring primarily as components of bacterial lipopolysaccharides rather than in widespread eukaryotic metabolism.

Ketoheptoses

Ketoheptoses constitute a subclass of heptoses, which are monosaccharides composed of seven carbon atoms, distinguished by the presence of a ketone functional group at the C-2 position in their linear form. This configuration positions a hydroxymethyl group (CH₂OH) at C-1 and another at C-7, with hydroxyl groups attached to the intervening carbons. The open-chain structure features four chiral centers at C-3, C-4, C-5, and C-6, enabling a total of 16 stereoisomers within the D-series (and an equivalent number in the L-series). In contrast to aldoheptoses, which possess an aldehyde group at C-1 and exhibit associated reactivity, ketoheptoses feature a that alters their chemical behavior and makes them more prevalent in pathways involving chain extensions, such as those building upon scaffolds. These structural distinctions influence their participation in specific biosynthetic processes, where the ketone group facilitates unique enzymatic interactions. Ketoheptoses like those derived from fructose extensions underscore their rarity and specialized roles in nature. Prominent stereoisomers include D-mannoheptulose, a naturally occurring ketoheptose abundant in avocado (Persea americana) fruit, where it serves as a major non-structural carbohydrate in the mesocarp and exocarp. Another key example is D-altro-heptulose, also referred to as sedoheptulose, which appears in various plants and is particularly significant in its phosphorylated form (sedoheptulose-7-phosphate) within metabolic intermediates. These compounds highlight the natural relevance of ketoheptoses, often linked to plant-specific carbohydrate storage and synthesis.

Properties

Physical Properties

Heptoses are typically white crystalline solids at , often appearing as colorless powders or needles, and they exhibit a hygroscopic nature, readily absorbing from the air due to their polar structure. These monosaccharides demonstrate high in , attributed to their multiple hydroxyl groups that facilitate with the ; for instance, sedoheptulose has a predicted exceeding 900 g/L. In contrast, heptoses are generally insoluble in non-polar solvents such as hydrocarbons or ethers, reflecting their hydrophilic character. The melting points of crystalline heptoses typically range from 75°C to 150°C, depending on the stereoisomer and hydration state. for heptoses in varies by , with D-series compounds generally exhibiting positive values; sedoheptulose shows [α]_D +2.5° (c=10, H_2O), while D-mannoheptose displays [α]^{20}_D +69° to +73°.

Chemical Properties

Heptoses, as monosaccharides with seven carbon atoms, exhibit reducing sugar behavior due to the presence of a free aldehyde group in aldoses or a ketone group in ketoheptoses that exists in equilibrium with the open-chain form, allowing them to reduce oxidizing agents such as Fehling's solution to form a red copper(I) oxide precipitate or Tollens' reagent to produce a silver mirror. This reactivity is characteristic of all reducing sugars and confirms the aldehydic or ketonic functionality in heptoses, with bromine water oxidation studies demonstrating their conversion to corresponding lactones at rates comparable to other aldoses. In , heptoses undergo , the reversible interconversion between α and β anomers via the open-chain form, leading to an mixture with values that stabilize over time. For example, measurements on D-mannoheptose hydrates show following a complex kinetic course, with rate constants (k₁ + k₂) on the order of 0.002 to 0.005 min⁻¹ at 20°C, slower than typical hexoses but indicative of the anomeric influenced by the extended carbon chain. This process is essential for the dynamic behavior of heptoses in solution, affecting their and reactivity. The anomeric carbon in heptoses (C-1 for aldoheptoses and C-2 for ketoheptoses) is highly reactive, enabling the formation of glycosidic bonds through nucleophilic attack by hydroxyl groups of other sugars or alcohols, resulting in α- or β-linkages that constitute oligo- and . In bacterial lipopolysaccharides, for instance, L-glycero-D-manno-heptose forms α-(1→3) or α-(1→7) glycosidic bonds, highlighting the versatility of this reactivity in biological contexts. Heptoses are readily oxidized at the anomeric carbon to form heptonic acids, such as D-glucoheptonic acid from aldoheptoses, using mild agents like , which selectively targets the group to yield the corresponding aldonic acid without affecting other hydroxyls. oxidation rates vary by , with β-forms reacting faster (e.g., velocity constant k × 10³ ≈ 56 for β-D-α-mannoheptose) than α-forms (k × 10³ ≈ 1.3), reflecting the accessibility of the reducing end. of heptoses with agents like or amalgamated converts the carbonyl to an alcohol, producing heptitols; for example, sedoheptulose yields sedoheptitol (also known as volemitol), a meso-heptitol with symmetric .

Occurrence and Examples

Natural Sources

Heptoses are prevalent in bacterial structures, serving as essential components of lipopolysaccharides (LPS) in Gram-negative bacteria, particularly within the inner core regions that anchor the outer membrane. These seven-carbon sugars contribute to the stability and integrity of the bacterial cell wall, with disruptions in their biosynthesis leading to truncated LPS and impaired bacterial viability. For instance, ADP-heptose intermediates are integral to this pathway across diverse Gram-negative species. In , heptoses accumulate notably in certain fruits and tissues, such as the ( americana), where mannoheptulose can constitute up to 5% of the dry weight in mesocarp and seed. This accumulation is particularly prominent during fruit development, highlighting avocados as a primary botanical reservoir for these sugars. Certain also harbor heptoses at low concentrations, often integrated into glycoconjugates or that support cellular functions in environments. Heptoses occur rarely in animals and other eukaryotes, appearing only in trace amounts within mammalian metabolism as transient intermediates rather than stable structural elements. This scarcity contrasts with their abundance in prokaryotes, underscoring a evolutionary divergence in carbohydrate utilization. Additionally, heptoses feature in microbial capsular polysaccharides (CPS) of pathogenic bacteria, such as certain strains of Escherichia coli, where they enhance virulence by modulating host interactions and immune evasion.

Notable Examples

Sedoheptulose, a ketoheptose with the D-altro configuration (D-altro-hept-2-ulose), was first isolated in 1917 from the leaves and stalks of the stonecrop plant Sedum spectabile by American chemists Francis B. La Forge and Charles S. Hudson. Its phosphorylated form, sedoheptulose-7-phosphate, serves as a key intermediate in the non-oxidative branch of the , facilitating the interconversion of sugars in cellular . Mannoheptulose, a ketoheptose featuring the D-manno configuration, was isolated in 1917 from (Persea americana) fruit by La Forge, marking one of the earliest identifications of a heptose in . This compound accumulates in unripe fruits, where it constitutes a significant portion of the soluble sugars. Another prominent heptose example is L-glycero-D-manno-heptose, an aldoheptose found in the inner core region of lipopolysaccharides (LPS) in such as . This heptose contributes to the structural integrity of LPS, which is associated with the endotoxic properties of bacterial cell walls. Heptoses like sedoheptulose and mannoheptulose are typically isolated from natural plant extracts through chromatographic techniques, including and ion-exchange chromatography, to separate them from other monosaccharides in complex mixtures.

Biosynthesis and Metabolism

Biosynthetic Pathways

Heptoses are biosynthesized primarily through pathways that generate sedoheptulose-7-phosphate as a key intermediate, derived from the non-oxidative branch of the (PPP) in both prokaryotes and eukaryotes. In the PPP, catalyzes the reversible transfer of a two-carbon unit from xylulose-5-phosphate to ribose-5-phosphate, yielding sedoheptulose-7-phosphate and glyceraldehyde-3-phosphate. This step is essential for producing seven-carbon sugars, with transaldolase subsequently facilitating further interconversions by transferring a three-carbon unit from sedoheptulose-7-phosphate to glyceraldehyde-3-phosphate, generating fructose-6-phosphate and erythrose-4-phosphate. In , sedoheptulose-7-phosphate serves as the precursor for nucleotide-activated heptoses used in (LPS) biosynthesis, via either the GDP-D-glycero-α-D-manno-heptose or ADP-L-glycero-β-D-manno-heptose pathways. The process begins with GmhA () converting sedoheptulose-7-phosphate to D-glycero-D-manno-heptose 7-phosphate. This intermediate is then acted upon by the bifunctional HldE, which first phosphorylates the C-1 position to form D-β-D-heptose 1,7-bisphosphate and then adenylylates it to produce ADP-D-β-D-heptose; GmhB dephosphorylates the C-7 position in an alternative route. For the ADP pathway prevalent in like Escherichia coli, the final step involves HldD (formerly RfaD or WaaD), an epimerase that converts ADP-D-β-D-heptose to ADP-L-glycero-β-D-manno-heptose for incorporation into the LPS inner core. The encoding these enzymes, such as gmhA, hldE, gmhB, and hldD (or rfaD), are often clustered in the and are essential for integrity. In eukaryotes, heptose biosynthesis is largely confined to the PPP for producing sedoheptulose-7-phosphate, which supports and synthesis. As of 2024, functional nucleotide-diphosphate (NDP)-heptose biosynthetic enzymes have been identified in eukaryotes, including and fungi, enabling the synthesis of NDP-heptoses such as ADP-heptose, potentially for glycoconjugates, protein , or innate immune signaling via pathways like ALPK1 . These enzymes exhibit cross-kingdom with bacterial HBEs. In vitro extensions from hexoses mimic the Kiliani-Fischer synthesis but are not primary routes; instead, aldolase-mediated condensations in the PPP indirectly contribute to heptose formation by integrating phosphates.

Metabolic Processes

In the (), sedoheptulose-7-phosphate serves as a key intermediate that facilitates the interconversion of sugars, where transaldolase catalyzes the reversible transfer of a three-carbon unit from sedoheptulose-7-phosphate to glyceraldehyde-3-phosphate, yielding erythrose-4-phosphate and fructose-6-phosphate, thereby integrating heptose-derived carbons into . This reaction helps balance the non-oxidative branch of the PPP, allowing heptose phosphates to contribute to the production of ribose-5-phosphate for nucleotide synthesis or to redirect carbons toward for energy generation. Heptose kinases play a crucial role in salvage pathways by phosphorylating free heptoses, such as sedoheptulose, to their corresponding 7-phosphate forms, enabling their entry into central carbon metabolism. The enzyme sedoheptulokinase (SHPK, also known as CARKL) specifically phosphorylates sedoheptulose using ATP, incorporating it into the and regulating carbohydrate flux in mammalian cells, including macrophages and T-cells, where it influences metabolic reprogramming and immune responses. mechanisms, though less characterized for heptoses, may occur via nonspecific phosphatases to recycle phosphates or modulate pool sizes during stress conditions. Catabolism of heptoses primarily involves their conversion to glycolytic intermediates after , often through aldolase-like reactions in the , such as the transaldolase-mediated cleavage that generates fructose-6-phosphate, a direct substrate. This process allows partial breakdown of the seven-carbon chain into three- and four-carbon units that feed into , but due to the rarity of heptoses in most organisms, their direct contribution to ATP yield remains minimal compared to glucose metabolism. Certain heptoses exhibit inhibitory effects in metabolism; for instance, D-mannoheptulose acts as a competitive inhibitor of glucokinase, the rate-limiting enzyme in glucose phosphorylation, thereby disrupting glucose sensing in pancreatic beta-cells and reducing insulin secretion in response to elevated blood glucose. This inhibition has been leveraged in studies to restore pulsatile insulin release in diabetic models by modulating glycolytic flux.

Biological Roles

Structural Functions

In bacterial lipopolysaccharides (LPS), heptose units such as L-glycero-D-manno-heptose form critical components of the inner core oligosaccharide, where they serve as branching points that connect the lipid A-Kdo region to the outer core and O-antigen, thereby maintaining the overall architecture and stability of the outer membrane. These heptose residues, often phosphorylated or glycosylated, introduce structural rigidity through their branched configurations, which prevent membrane permeability and support the endotoxic properties of Gram-negative bacteria. Heptoses are also incorporated into surface glycans and , enhancing by contributing to the structural integrity of O-antigens and capsular (). In O-antigens, heptose residues form part of repeating units that shield the bacterial surface and modulate host interactions, while in , modified heptoses such as those in promote resistance to and serum killing. Although predominantly microbial, heptoses play minor roles in certain eukaryotic structures, including extensions in plant cell walls where they occasionally appear in specialized , and in algal glycans such as those of like Codium yezoense, where D-glycero-D-galacto-heptose contributes to sulfated galactan frameworks. By providing branching points in these chains, heptoses enhance overall rigidity and mechanical stability, facilitating environmental adaptation in these organisms.

Signaling and Regulatory Roles

Heptose-1,7-bisphosphate (HBP), an intermediate in the of (LPS) in , serves as a that triggers innate immune responses in mammalian hosts. Upon detection by the cytosolic ALPK1, HBP induces oligomerization and of TIFA, which in turn promotes signaling and amplifies the NLRP3 pathway. This leads to the production of pro-inflammatory cytokines such as IL-1β, contributing to antimicrobial defense during bacterial . As of 2025, recent studies have revealed additional roles for the ALPK1-TIFA pathway activated by HBP or related ADP-heptose, including promotion of intestinal regeneration in response to bacterial detection, contribution to ageing-related clonal , and modulation of responses in like . Mannoheptulose, a naturally occurring heptose derived from like avocados, acts as a competitive inhibitor of , a key in glucose sensing and insulin in pancreatic β-cells. By reducing glucokinase activity, mannoheptulose modulates glucose-stimulated insulin release, preventing excessive insulin under hyperglycemic conditions. This inhibitory property has been exploited in research since the 1960s to study β-cell function and explore therapeutic strategies for , including restoration of pulsatile insulin in dysfunctional islets. As of 2025, recent investigations in islets and models confirm mannoheptulose's ability to prevent hyperglycemic adaptations and support beta-cell . Heptose-containing glycans on bacterial glycoproteins play critical roles in pathogen-host interactions, particularly in facilitating and modulating immune recognition. For instance, in Actinobacillus actinomycetemcomitans, the aah gene encodes a that adds heptose residues to proteins, enhancing bacterial adherence to host components and promoting formation during periodontal infections. These modified glycans also influence host signaling by interacting with on immune cells, thereby aiding evasion of and contributing to in host tissues. In the (), sedoheptulose-7-phosphate functions as a pivotal intermediate in the non-oxidative branch, enabling the reversible interconversion of sugars to balance the production of NADPH and ribose-5-phosphate according to cellular demands. This regulatory flexibility, driven by metabolite levels and , helps direct flux away from the oxidative phase when reductive power is sufficient, thus maintaining metabolic and preventing excess NADPH production under non-stress conditions.