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Auer rod

Auer rods, also known as Auer bodies, are distinctive needle-shaped crystalline inclusions found in the of myeloid blast cells, serving as a hallmark morphological feature of (AML) and certain other myeloid neoplasms. These azurophilic structures, typically appearing as linear or comma-like forms under light microscopy, are composed of fused lysosomes rich in lysosomal enzymes and nucleoproteins, and they exhibit strong positivity on cytochemical stains such as (MPO), Sudan black B, periodic acid-Schiff (PAS), and peroxidase. First described in 1903 by American pathologist John Auer in a patient with at , these inclusions are for myeloid differentiation and are most commonly observed in the blasts of AML subtypes M1 through M6. The diagnostic significance of Auer rods lies in their ability to confirm the myeloid origin of leukemic cells, distinguishing AML from lymphoid leukemias and aiding in the classification of disease subtypes, particularly in (APL, AML M3) where multiple bundled Auer rods—termed faggot cells—are a classic finding. Their presence in peripheral blood or smears is highly specific for myeloid neoplasms, though rare occurrences have been reported in non-myeloid conditions such as neoplasms or even , often as mimics rather than true Auer rods. In myelodysplastic syndromes (MDS), the detection of Auer rods upgrades the diagnosis to a higher-risk category, such as MDS with excess blasts-2 (MDS-EB-2), indicating progression toward AML. Beyond , Auer rods carry prognostic ; in non-APL AML, their presence is generally associated with a more favorable response to intensive and improved overall survival compared to Auer rod-negative cases. Persistence of Auer rods post-treatment signals residual disease and lack of remission, guiding therapeutic decisions. While electron microscopy reveals their ultrastructural details as crystalline arrays within lysosomes, modern and complement their morphological identification to refine risk stratification and targeted therapies in myeloid malignancies.

Overview

Definition

Auer rods are large, crystalline cytoplasmic characteristically observed in the myeloid blast cells of patients with certain myeloid neoplasms. These structures represent fused primary granules within immature myeloid precursors, such as myeloblasts and promyelocytes, and are a hallmark feature of abnormal myeloid differentiation. Morphologically, Auer rods appear as azurophilic, needle-like or rod-shaped formations, often staining pink or red due to their content, and are readily visible under light microscopy in Romanowsky-stained preparations. This distinctive appearance arises from the coalescence of azurophilic granules, distinguishing them from other cytoplasmic inclusions. The presence of Auer rods is associated with abnormal hematologic conditions, including (AML) and its subtype (APL), high-grade myelodysplastic syndromes (MDS), and rarely in certain such as (CMML). They are not found in normal or reactive myeloid cells, underscoring their specificity for neoplastic processes. In clinical practice, Auer rods serve as a key indicator of myeloid lineage involvement in suspected leukemias.

Morphology

Auer rods exhibit a distinctive crystalline appearance under light microscopy, characterized by their refractile quality and varied shapes that include needles, commas, diamonds, rectangles, corkscrews, or granules. These structures often fuse into bundles, particularly in (), where they form characteristic faggot cells with multiple aligned rods in the . They are exclusively located within the of cells of the myeloid , such as myeloblasts and promyelocytes, and are not observed in the or in lymphoid cells. In terms of size, Auer rods typically measure 1–6 micrometers in length, appearing as slender, rod-like or spindle-shaped inclusions that vary in thickness. Their refractile nature makes them prominent against the cellular background, aiding visual . Under electron , Auer rods reveal a rod-like array of tubular structures, often arranged hexagonally with a periodicity of approximately 13-26 nm in cases, distinguishing their ultrastructural organization from other inclusions. This tubular architecture underscores their crystalline at the subcellular level.

History

Discovery

Auer rods were first described in 1905 by Canadian physician Thomas McCrae while examining blood smears from a patient with at . McCrae noted refractile, rod-shaped inclusions within large mononuclear cells, which he interpreted as lymphocytes, and illustrated them in his report of five leukemia cases, initially suggesting they might represent bacterial elements or degenerative changes. These structures were soon re-evaluated, with early interpretations shifting from possible lymphoblasts or inclusions to features indicative of myeloid lineage by 1906. In that year, American pathologist John Auer published a detailed account confirming the presence of similar needle-like bodies in myeloblasts from the same patient, providing illustrations and emphasizing their distinct in what he also initially classified as acute lymphatic . Auer explicitly acknowledged McCrae's prior observation of the same case material, marking an early instance of overlapping reporting in . Subsequent investigations in the mid-20th century advanced understanding of their nature. In 1950, pathologist Gerald A. Ackerman employed microscopic and histochemical techniques to demonstrate that Auer bodies exhibited crystalline characteristics, with positive staining for substances like and proteins, supporting their origin from abnormal fusion in leukemic cells. These findings laid foundational evidence for their ultrastructural properties, later corroborated by electron microscopy studies. The structures are named in honor of John Auer for his confirmatory work.

Eponym

The eponym "Auer rod" derives from John Auer (1875–1948), an American physician, , and renowned for his contributions to experimental . Born in , Auer initially trained in and joined the laboratory of at in 1903, where he conducted early observations on leukemic cells. His career later shifted to the Rockefeller Institute for Medical Research, where he served as an associate in and , authoring nearly 150 scientific papers on topics ranging from to vascular . Auer's key contribution to came from his 1906 study, in which he meticulously described rod-shaped cytoplasmic inclusions observed in the large mononuclear cells (later identified as myeloblasts) of a with . Titled "Some hitherto undescribed structures found in the large lymphocytes of a case of acute leukaemia," the paper, published in the American Journal of the Medical Sciences, highlighted these refractile, needle-like bodies visible in wet-film blood preparations, initially misinterpreted as artifacts or bacterial forms but later recognized as features of myeloid neoplasms. This work, authorized by Osler and supported by colleague Thomas McCrae, provided the first illustrated and detailed account, solidifying the structures' diagnostic significance. Although Canadian physician Thomas McCrae reported similar rod-like inclusions in 1905 in a series of cases published in the British Medical Journal, predating Auer's formal description, the honors Auer due to his comprehensive confirmatory analysis and the prominence of his publication in establishing the feature's recognition. McCrae's brief mention in a clinical report lacked the depth of Auer's pathological examination, leading to ongoing debates about priority but affirming Auer's role in popularizing the term. In medical nomenclature, Auer rods exemplify the tradition of eponyms for distinctive cellular inclusions, such as or Dutcher bodies, which commemorate pivotal observers to facilitate precise communication in .

Pathophysiology

Formation

Auer rods originate from the abnormal of primary (azurophilic) lysosomes in leukemic myeloid cells, arising due to disrupted myeloid during leukemogenesis. In normal , primary granules form in promyelocytes and mature progressively, but in (AML), this process is arrested, leading to excessive accumulation and coalescence of these lysosomes into crystalline structures within the of blasts. This is a hallmark of neoplastic transformation in myeloid lineages, particularly in subtypes exhibiting partial . Genetic mutations play a central role in perturbing granule maturation and promoting Auer rod development. For instance, the PML-RARA in () encodes a chimeric protein that blocks myeloid differentiation at the promyelocyte stage, impairing normal lysosomal trafficking and enzyme packaging. This disruption results in aberrant of immature , as the protein interferes with signaling essential for maturation. Auer rods are also associated with certain AML subtypes, such as those with RUNX1::RUNX1T1 or CBFB mutations, which are linked to myeloid neoplasms featuring these structures. Intracellularly, Auer rods assemble through the crystallization of enzymes such as (MPO) within fused lysosomal compartments during the of blast cells. MPO, a key component of azurophilic granules, aggregates into needle-like crystalline arrays under the altered and ionic conditions of the neoplastic lysosomes, forming the characteristic rod morphology. This process occurs predominantly in rapidly dividing blasts, where unchecked granule synthesis overwhelms degradative pathways. Although the key processes of lysosomal fusion and enzyme crystallization are established, the precise functional role and full molecular mechanisms of Auer rod formation remain areas of ongoing research. Factors influencing Auer rod formation include dysregulated and enhanced lysosomal in high-grade myeloid neoplasms. Blocked in leukemic cells prevents the clearance of abnormal lysosomes, allowing persistent and . In high-grade AML, upregulated lysosomal biogenesis—driven by oncogenic signaling—facilitates excessive membrane , concentrating hydrolytic enzymes into rod structures. These mechanisms underscore the neoplastic specificity of Auer rods, distinguishing them from normal granulocyte development.

Composition

Auer rods are primarily composed of fused lysosomal granules derived from azurophilic granules, rich in a variety of enzymatic components characteristic of myeloid lineage cells. These structures contain key lysosomal enzymes, including (MPO), , cathepsin G, and , which are stored in the primary granules of promyelocytes and myelocytes. The presence of these enzymes reflects the abnormal fusion and aggregation of azurophilic granules during leukemic transformation in myeloid precursors. The crystalline that defines the rod-like of Auer rods is formed through the and of MPO molecules, which imparts the characteristic azurophilic staining properties observed under light microscopy. This MPO-rich core is embedded within a of other granular proteins, contributing to the dense, refractive of the inclusions. Ultrastructural analysis via electron microscopy reveals Auer rods as electron-dense arrays, often arranged in hexagonal patterns with a periodicity of approximately 25 nm, confirming their lysosomal origin and crystalline organization. These structures are visualized as parallel arrays within a membrane-bound compartment, highlighting the condensed enzymatic content. Auer rods are highly specific to myeloid cells and are not typically found in non-myeloid cells, such as lymphoid blasts or non-hematopoietic tissues, underscoring their utility as a diagnostic marker for myeloid neoplasms. This lineage restriction arises from the exclusive expression of the constituent azurophilic granule enzymes in myeloid differentiation pathways.

Associated Conditions

Auer rods are primarily associated with (AML), where they serve as a feature in certain subtypes. They are most frequently observed in AML with maturation (FAB ) and (APL, FAB M3), the latter characterized by the t(15;17) translocation involving PML-RARA. In APL, which comprises 5-10% of AML cases, Auer rods are present in up to 70-80% of hypergranular variant cases, often appearing as multiple bundled structures known as faggot cells in abnormal promyelocytes. Overall, Auer rods occur in approximately 50% of AML cases across subtypes, with higher prevalence (around 60-78%) in M2 and lower rates (10-20%) in monocytic (M4/M5) or erythroid () variants. Auer rods also appear in high-grade myelodysplastic syndromes (MDS), particularly MDS with excess blasts-2 (MDS-EB-2, formerly RAEB-2), where their presence reclassifies the condition as higher risk regardless of blast percentage. Prevalence in MDS-EB-2 is about 11%, and these cases exhibit mutational profiles resembling AML, including higher frequencies of , FLT3, and IDH mutations, portending faster progression to AML. In (CMML), Auer rods are rare but diagnostic for CMML-2 when detected, even with blast counts below 5% in peripheral blood or 10% in , indicating an aggressive proliferative phase. Rarely, Auer rods occur in acute lymphoblastic leukemia (ALL) with aberrant myeloid markers or in mixed phenotype acute leukemia, typically reflecting lineage infidelity rather than pure lymphoid disease; such cases represent exceptional diagnostic challenges. They have also been reported in therapy-related myeloid neoplasms following cytotoxic chemotherapy or radiation, often in association with complex karyotypes and poor prognosis. Additionally, isolated instances appear in blastic plasmacytoid dendritic cell neoplasm (BPDCN), a rare hematologic malignancy, where they may mimic myeloid features but do not alter the plasmacytoid immunophenotype. In non-APL AML, the presence of Auer rods carries prognostic implications, often correlating with favorable response to intensive in pediatric cases (e.g., higher complete remission rates) but variable outcomes in adults depending on .

Diagnostic Role

Auer rods serve as a key morphological feature in the diagnosis of myeloid neoplasms, being for blasts of myeloid lineage and thereby confirming (AML) over (ALL), where such structures are absent. Their identification in leukemic cells excludes lymphoid malignancies and supports the myeloid differentiation essential for accurate classification. In the (WHO) classification system, the presence of Auer rods bolsters the diagnosis of AML when blasts comprise at least 20% of nucleated cells in the or peripheral , providing morphological evidence of myeloid commitment alongside immunophenotypic and genetic data. Furthermore, in myelodysplastic syndromes (MDS), Auer rods elevate the risk stratification, classifying cases as MDS with increased blasts grade 2 even if blast counts are below 20%, highlighting their role in identifying progression toward AML. Prognostically, Auer rods are associated with a more favorable outcome in AML, correlating with higher complete remission rates and improved survival due to markers of differentiation and responsiveness to therapy. In (APL), bundles of multiple Auer rods—termed "faggot cells"—are highly specific and indicate strong responsiveness to all-trans (ATRA) and , contributing to cure rates exceeding 90% in treated patients. In differential diagnosis, Auer rods help distinguish myeloid neoplasms from infectious processes or staining artifacts; for instance, Phi bodies in reactive neutrophils during infections may superficially resemble Auer rods but differ in composition and lack azurophilic staining. The observation of multiple Auer rods as faggot cells is particularly diagnostic for APL, aiding in rapid subtype identification amid other AML variants.

Detection and Identification

Microscopy Techniques

Light microscopy serves as the standard method for the initial detection of Auer rods in clinical samples, particularly in aspirates and peripheral blood smears. These specimens are typically prepared as thin, air-dried smears to preserve cellular morphology, followed by with Wright-Giemsa or other Romanowsky-type stains, which highlight the , needle-like appearance of Auer rods within the of myeloid blasts. For optimal , high-resolution objectives at 100× magnification (total 1000×) are employed, allowing clear differentiation of the slender, refractile rods from surrounding cellular structures. Electron microscopy, particularly (TEM), is utilized in research settings to confirm the presence of Auer rods and elucidate their when light microscopy findings are ambiguous or for detailed characterization. Ultrathin sections of fixed cells reveal Auer rods as dense, crystalline lattices formed by fused azurophilic granules, exhibiting a three-dimensional monoclinic with specific dimensions, such as edge lengths of approximately 6.6 nm, 8.6 nm, and 9.6 nm. This technique has been instrumental in distinguishing Auer rods in variants like hypogranular , where primary granules are not readily apparent under light microscopy.

Staining Methods

Auer rods are commonly identified using Romanowsky-type stains, such as Wright-Giemsa, in which they appear as distinct red-purple, needle-shaped structures within the of myeloid precursor cells due to their affinity for the azurophilic granules rich in (MPO). These stains provide initial visualization under light , highlighting the rods' characteristic morphology, though detection rates are relatively lower compared to specialized cytochemical methods. Peroxidase cytochemistry, particularly the MPO stain, offers enhanced sensitivity for confirming Auer rods, demonstrating strong positivity that underscores their myeloid lineage and often reveals structures not apparent with routine Romanowsky stains—for instance, increasing detection threefold in cases. As an alternative, Sudan Black B cytochemistry also exhibits positivity in Auer rods by binding to components of the granules, aiding in from non-myeloid inclusions. Immunocytochemistry employs anti-MPO antibodies to specifically label Auer rods, providing precise localization in smears, , or tissue sections, which is particularly valuable when cytochemical results are equivocal or for archival material. Distinguishing Auer rods from artifacts like Charcot-Leyden crystals or relies on staining patterns: Auer rods show intense MPO and Sudan Black B positivity with rod-like morphology, whereas Charcot-Leyden crystals, derived from , are MPO-negative and bipyramidal, and display variable Gram staining without azurophilic affinity.