Disproven Facts
Biology

Biological sex is strictly binary: male or female, determined by XX or XY chromosomes.

Now we know:

Biological sex is a spectrum involving chromosomes, hormones, anatomy, and genetics. Intersex conditions occur in approximately 1.7% of births. The SRY gene is the primary determinant, but exceptions exist.

Disproven 1993

What changed?

In most secondary school biology curricula, the lesson was brief and tidy: females have two X chromosomes, males have one X and one Y. The chromosomes determine sex. Sex is determined at fertilization. The categories are two, and every human being belongs to one or the other. The simplicity was pedagogically appealing and seemed, on casual inspection, to match observable reality well enough.

The biology, examined carefully, was always more complicated. The history of genetics knew as much. The existence of XXY individuals, described systematically by Harry Klinefelter in 1942, was documented long before molecular mechanisms were understood. Turner syndrome (XO), Klinefelter syndrome (XXY), and XYY karyotypes were catalogued in the medical literature across the 1940s and 1950s, and their existence was not secret; it was simply quarantined to clinical medicine and not incorporated into the general biology classroom.

The chromosome story became still more nuanced in 1990, when Andrew Sinclair and colleagues at the Imperial Cancer Research Fund in London published a paper in Nature identifying SRY, the sex-determining region Y gene, as the primary switch for testicular development. The paper, titled "A gene from the human sex-determining region encodes a protein with homology to a conserved DNA-binding motif," showed that SRY presence drives the embryonic gonad toward testicular differentiation. But exceptions documented in subsequent years made clear that the switch was not absolute: XX individuals with a translocated SRY fragment develop as males; XY individuals with SRY mutations develop as females. The gene matters; the chromosome is a delivery vehicle.

Beyond chromosomes and the SRY gene, the developmental pathway from genotype to anatomy involves hormonal signaling at multiple stages, receptor sensitivity, and the interaction of dozens of other genes. Congenital adrenal hyperplasia, complete androgen insensitivity syndrome, 5-alpha reductase deficiency, and Mullerian agenesis each produce anatomical configurations that do not fit the binary template, and each arises through a distinct mechanism. Anne Fausto-Sterling's 2000 book Sexing the Body drew on medical literature to estimate that approximately 1.7 percent of births involve some degree of difference in sex characteristics from the standard male or female pattern, a figure that has been debated, with estimates ranging considerably depending on how "intersex" is defined, but which confirmed that biological variation in this domain is neither negligible nor exotic.

What the genetics and embryology revealed, collectively, was not that sex is a social construction but that it is a biological system with multiple interacting components, chromosomes, gonadal tissue, hormonal environment, receptor function, and anatomy, none of which invariably aligns with all the others. The binary model described the most common developmental outcome. It did not describe the full range of human biology. For generations, the medical response to that range had been surgical and hormonal intervention on intersex infants to enforce conformity with the binary, a practice that the human rights community, beginning in the 1990s, and an increasing number of medical ethicists began to characterize as ethically problematic. The reckoning began, as it often does, with the science finally being read.

At a glance

Disproven
1993
Believed since
1946
Duration
47 years
Taught in schools
1946 – 1993

Sources

  1. [1] A gene from the human sex-determining region encodes a protein with homology to a conserved DNA-binding motif - Sinclair, Andrew H. et al., 1990
  2. [2] How common is intersex? A response to Anne Fausto-Sterling - Sax, Leonard, 2002

See also

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You were taught:

Male pattern baldness is inherited from your mother's side of the family.

Now we know:

Male pattern baldness is polygenic, involving variants from both maternal and paternal chromosomes. The androgen receptor gene on the X chromosome plays a significant role but multiple loci on autosomes also contribute.

Disproven2008
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Biology
You were taught:

One gene controls one trait, and mapping the human genome would explain most diseases.

Now we know:

Most traits and diseases are polygenic—shaped by hundreds of genes interacting with each other and the environment. The 98% of the genome once dismissed as 'junk DNA' turned out to contain regulatory elements essential to gene expression.

Disproven2003
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Biology
You were taught:

Cloning an animal would produce an exact physical and behavioral duplicate of the original.

Now we know:

Cloning produces a genetic copy but not an identical individual. Epigenetics, developmental variation, and environment mean cloned animals differ from their genetic source in appearance, behavior, and health. Dolly the sheep (born July 1996, announced February 1997) was the first cloned mammal from an adult cell.

Disproven1997
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Biology
You were taught:

Humans have 206 bones as adults, and this number is fixed and universal.

Now we know:

The number of bones varies individually. Many adults have extra ribs, sesamoid bones, or fused/split bones. The exact count ranges from 206 to over 270 in infants whose bones haven't fused.

Disproven2000
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